AD8113JST Datasheet, PDF(15/28 Page) Analog Devices – Audio/Video 60 MHz 16 X 16, G = + 2 Crosspoint Switch

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AD8113JST Datasheet, PDF (15/28 Pages) Analog Devices – Audio/Video 60 MHz 16 X 16, G = + 2 Crosspoint Switch

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AD8113

CALCULATION OF POWER DISSIPATION

4.0

TJ = 150ØC

3.5

3.0

2.5

2.0

AMBIENT TEMPERATURE â ØC

Figure 6. Maximum Power Dissipation vs. Ambient

Temperature

The above curve was calculated from

( ) PD, MAX =

TJUNCTION , MAX â TAMBIENT

Î¸ JA

As an example, if the AD8113 is enclosed in an environment at

50Â°C (TA), the total on-chip dissipation under all load and supply

conditions must not be allowed to exceed 2.5 W.

When calculating on-chip power dissipation, it is necessary to

include the rms current being delivered to the load, multiplied

by the rms voltage drop on the AD8113 output devices. The

dissipation of the on-chip, 4 kâ¦ feedback resistor network must

also be included. For a sinusoidal output, the on-chip power

dissipation due to the load and feedback network can be approxi-

mated by

( ) PD , MAX =

AVCC â VOUTPUT, RMS

Ã IOUTPUT, RMS

ï£«ï£ï£¬VOUT4PUkTâ¦, RMS 2

ï£¶

ï£·

ï£¸

For nonsinusoidal output, the power dissipation should be cal-

culated by integrating the on-chip voltage drop multiplied by the

load current over one period.

The user may subtract the quiescent current for the Class AB

output stage when calculating the loaded power dissipation. For

each output stage driving a load, subtract a quiescent power

according to

( ) PD, OUTPUT = AVCC â AVEE Ã IO, QUIESCENT

For the AD8113, IO, QUIESCENT = 0.67 mA.

For each disabled output, the quiescent power supply current in

AVCC and AVEE drops by approximately 1.25 mA, although

there is a power dissipation in the on-chip feedback resistors if

the disabled output is being driven from an external source.

AVCC

QNPN

QPNP

IO, QUIESCENT

VOUTPUT

4kâ

IOUTPUT

AGND

IO, QUIESCENT

AVEE

Figure 7. Simplified Output Stage

An example: AD8113, in an ambient temperature of 70Â°C,

with all 16 outputs driving 6 V rms into 600 â¦ loads. Power

supplies are Â± 12 V.

Step 1. Calculate power dissipation of AD8113 using data sheet

quiescent currents.

PD, QUIESCENT = (AVCC Ã IAVCC) + (AVEE Ã IAVEE) + (DVCC Ã IDVCC)

PD, QUIESCENT = (12 V Ã 54 mA) + (â12 V Ã â54 mA)

+ (5 V Ã 13 mA)

Step 2. Calculate power dissipation from loads.

PD, OUTPUT = (AVCC â VOUTPUT, RMS) Ã IOUTPUT, RMS

+ VOUTPUT2/4 kâ¦

PD, OUTPUT = (12 V â 6 V) Ã 6 V/600 â¦ + (6 V )2/4 kâ¦ = 69 mW

There are 16 outputs, so

nPD, OUTPUT = 16 Ã 69 mW = 1.1 W

Step 3. Subtract quiescent output current for number of loads

(assumes output voltage >> 0.5 V).

PDQ, OUTPUT = (AVCC â AVEE) Ã IO, QUIESCENT

PDQ, OUTPUT = (12 V â (â12 V)) Ã 0.67 mA = 16 mW

There are 16 outputs, so

nPD, OUTPUT = 16 Ã 16 mW = 0.3 W

Step 4. Verify that power dissipation does not exceed maximum

allowed value.

PD, ON-CHIP = PD, QUIESCENT + nPD, OUTPUT â nPDQ, OUTPUT

PD, ON-CHIP = 1.3 W + 1.1 W â 0.3 W = 2.1 W

From the figure or the equation, this power dissipation is below

the maximum allowed dissipation for all ambient temperatures

approaching 70Â°C.

NOTE: It can be shown that for a dual supply of Â± a, a Class AB

output stage dissipates maximum power into a grounded load

when the output voltage is a/2. So for a Â± 12 V supply, the

above example demonstrates the worst-case power dissipation

into 600 â¦. It can be seen from this example that the minimum

load resistance for Â± 12 V operation is 600 â¦ (for full rated oper-

ating temperature range). For larger safety margins, when the out-

put signal is unknown, loads of 1 kâ¦ and greater are recommended.

When operating with Â± 5 V supplies, this load resistance may be

lowered to 150 â¦.

REV. A

â15â

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