AB-039 Datasheet, PDF(3/6 Page) Burr-Brown (TI) – POWER AMPLIFIER STRESS AND POWER HANDLING LIMITATIONS

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AB-039 Datasheet, PDF (3/6 Pages) Burr-Brown (TI) – POWER AMPLIFIER STRESS AND POWER HANDLING LIMITATIONS

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200

180

160

140

120

100

POWERâCONTINUOUS dc

1.0

0.9

Power from

Power Supply

0.8

0.7

0.6

0.5

Power Delivered 0.4

to Load

0.3

0.2

Worst

Case

0.1

10 20 30 40 50 60 70 80 90 100

DC Output Voltage (% of V+ Supply)

Power Dissipation

of Amplifier

Amplifier

Dissipation

Power

Supply

Power

Delivered

to Load

FIGURE 3. DC Power Dissipation, Resistive Load.

Example 2

An unbalanced power supply is often used with power

amplifiers to allow a large unipolar output voltage. A

+70V/â5V power supply is used with the OPA502 to

drive a 30â¦ load connected to ground. What is the worst

case power dissipation and SOA requirement?

Answerâ

The worst case occurs at half output, where VO = 35V,

and VCE = 35V. The output current at this point would

be 35V/30â¦ = 1.17A which is within the SOA. Power

dissipation would be 35V â¢ 1.17A = 41W.

Other points to consider: The maximum output voltage

would be approximately 65V, and 65V/30â¦ = 2.17A.

At this point, VCE = 5V, a safe value on the SOA.

If the current limit were set to accommodate the full

output of 2.17A, it would not be safe for short-circuits

to ground. With a short-circuit to ground, VCE = 70V

where the maximum safe current is 0.4A.

PULSED OPERATION

Some applications must handle pulses of current or varying

current waveforms with a low duty-cycle. The SOA plot

sometimes shows an ability to supply larger currents for

short duration pulses. In Figure 2, the SOA limits are labeled

for 5ms, 1ms and 0.5ms pulses. The duty-cycle must be low

(approximately 5% or less), so that heating in the output

transistor is given time to dissipate.

Unusual current waveforms can be estimated with an ap-

proximation to a rectangular pulse as shown in Figure 4.

With a resistive load, the most stressful condition is when

the output voltage is approximately half the supply voltage

as shown. For other types of loads, evaluate any condition

that produces significant load current and high VCE. Appli-

cations which pulse currents beyond the dc SOA of the

amplifier should be evaluated very carefully since they are

pushing the limits of the device. Good reliability is achieved

by taking a conservative approach to SOA limits.

Supply Voltage

V+

VCE = (V+)/2

Output Voltage

Waveform

Equivalent

Rectangular Pulse

Equivalent Duration

FIGURE 4. Pulsed Loads.

AC SIGNALS

Imagine a time-varying signal that rapidly transverses the

curves in Figure 3. The point of maximum dissipation is

passed only briefly. If the signal changes rapidly enough

(above 50Hz), the thermal time constant of the device causes

the junction temperature to be determined by the average

power dissipation. So, ac applications are generally less

demanding than dc applications of the same peak voltage

and current requirements.

If the signal is bipolar, such as a sine wave centered around

zero, each output transistor ârestsâ for a half-cycle. The total

amplifier dissipation is shared between the two output tran-

sistors, lowering the effective thermal resistance of the

package.

If the instantaneous peak dissipation point is within the SOA

of the amplifier, the primary concern is providing a suffi-

cient heat sink to prevent overheating. Since this peak

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