LUCL9216AGF-D AGERE [Agere Systems], LUCL9216AGF-D Datasheet - Page 22

LUCL9216AGF-D

Manufacturer Part Number

LUCL9216AGF-D

Description

Short-Loop Ringing SLIC with Ground Start

Manufacturer

AGERE [Agere Systems]

Datasheet

1.LUCL9216AGF-D.pdf (48 pages)

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Short-Loop Ringing SLIC with Ground Start

Applications

Power Control

Under normal device operating conditions, power dissi-

pation on the device must be controlled to prevent the

device temperature from rising above the thermal shut-

down and causing the device to shut down. Power dis-

sipation is highest with higher battery voltages, higher

current limit, and under shorter dc loop conditions.

Additionally, higher ambient temperature will also

reduce thermal margin.

To support required power ringing voltages, this device

is meant to operate with a high-voltage primary battery

(–65 V to –75 V typically). Thus, power control is nor-

mally achieved by use of the battery switch and an aux-

iliary lower absolute voltage battery. Operating

temperature range, maximum current limit, maximum

battery voltage, minimum dc loop length and protection

resistor values, airflow, and number of PC board layers

will influence the overall thermal performance. The fol-

lowing example illustrates typical thermal design con-

siderations.

The thermal resistance of the 28-pin PLCC package is

typically 35.5 C/W, which is representative of the natu-

ral airflow as seen in a typical switch cabinet with a

multilayer board.

The L9216 will enter thermal shutdown at a tempera-

ture of 150 C. The thermal design should ensure that

the SLIC does not reach this temperature under normal

operating conditions.

For this example, assume a maximum ambient operat-

ing temperature of 85 C, a maximum current limit of

30 mA, a maximum battery of –75 V, and an auxiliary

battery of –21 V. Assume a (worst-case) minimum dc

loop of 20

tors, and 200

the effects of parameter tolerance.

1. T

2. Allowed thermal rise = package thermal

impedance

65 °C = 35.5 °C/W

SLIC power dissipation (P

150 °C – 85 °C = 65 °C.

TSD

– T

AMBIENT(max)

of wire resistance, 30

•

for the handset. Additionally, include

SLIC power dissipation.

•

= allowed thermal rise.

SLIC power dissipation

) = 1.83 W.

protection resis-

Thus, if the total power dissipated in the SLIC is less

than 1.83 W, it will not enter the thermal shutdown

state. Total SLIC power is calculated as:

For the L9216, the worst-case SLIC on-hook active

power is 75 mW. Thus,

The power dissipated in the SLIC is the total power dis-

sipation less the power that is dissipated in the loop.

Thus, under the operating conditions of this example,

the thermal design, using the auxiliary, is adequate to

ensure the device is not driven into thermal shutdown

under worst-case operating conditions.

Total P

limit + SLIC quiescent power.

Total off-hook power = (I

tolerance)*(V

Total off-hook power = (0.030 A)(1.08) * (21) +

75 mW

Total off-hook power = 755.4 mW

SLIC P

Loop off-hook power = (I

min + 2R

Loop off-hook power = (0.030 A)(1.08)

Loop off-hook power = 293.9 mW

SLIC off-hook power = Total off-hook power – loop

off-hook power

SLIC off-hook power = 755.4 mW – 293.9 mW

SLIC off-hook power = 461.5 mW < 1.83 W

+ 200

= maximum battery

= total power – loop power

HANDSET

BATAPPLIED

)

) + SLIC on-hook power

LOOP

•

)(current-limit

maximum current

* 1.08)

September 2001

Agere Systems Inc.

•

(20

LOOP(dc)

LUCL9216AGF-D AGERE [Agere Systems], LUCL9216AGF-D Datasheet - Page 22

LUCL9216AGF-D

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