AN47 Datasheet, PDF(1/6 Page) Zetex Semiconductors – Getting more out of the ZXLD1350

English

English German Russian Spanish Italian Polish Chinese Japanese Korean French Portuguese	Language :

AN47 Datasheet, PDF (1/6 Pages) Zetex Semiconductors – Getting more out of the ZXLD1350 - dimming techniques

AN47

Si321X LINEFEED POWER MONITORING AND PROTECTION

Introduction

The Silicon Laboratoriesâ ProSLIC products are

designed to continuously monitor the power dissipated

in each of the six external bipolar transistors in the

linefeed circuit. These power measurement results are

available to the user in software registers and are also

used by the ProSLIC to protect linefeed transistors from

damage due to overpower conditions. Using proper

power threshold and thermal low-pass filter settings, the

ProSLIC will either alert the user or automatically

transition the open state in the event of an overpower

condition.

Power Threshold

The thermal resistance (RTHJA) of the transistor is

improved when it is mounted on a PCB board. This

improvement depends on the PCB size, the material it is

made of, and the amount of the copper surface on the

PCB board. Figure 1 illustrates how the board material,

available board area, and the amount of copper present

influence the thermal resistance of the transistors. This

chart can be obtained from the transistor manufacturer if

not included in the transistor data sheet.

450

As the dissipated power in linefeed transistors

increases, so does the junction temperature of the

transistor die. The maximum admissible junction

temperature must not be exceeded because this could

damage or destroy the transistor die. In the Si321x, the

measured power consumed in each of the transistors is

compared to the power threshold values in the

corresponding indirect registers. If the power in any

external transistor exceeds the programmed threshold

(after passing through a user-programmable low pass

filter which will be explained in the next section), a

power alarm is triggered to indicate line fault condition.

Unless the auto-open feature is disabled (direct

the open state.

The value of the power threshold is calculated based on

the characteristic of the transistors used. Transistor

manufacturers provide this information in terms of

thermal resistance for each transistor package. The

relationship between the maximum junction

temperature and the maximum power that can be

dissipated by the transistor package is defined in the

following equation:

TJMAX = TAMB + PMAX Ã RTHJA

where TJMAX is the maximum junction temperature

(usually 150 Â°C), TAMB is the ambient temperature

(70 Â°C for commercial rating), and PMAX is the

maximum power allowance on the transistor package.

RTHJA is the junction to ambient thermal resistance of

the transistor package.

300

150

FR4 Min. Copper

SRBP Min. Copper

SRBP Max. Copper

FR4 Max. Copper

0.01

0.1

P.C.B. Area (Sq.Ins.)

Thermal Resistance v P.C.B. Area

Figure 1. SOT23

In practice, the transistors are normally mounted on a

PCB with several square inches area, but for illustration

purposes consider a model in which the transistor

package is mounted on 1-inch square of FR4 PCB with

0.25-inch square of copper surface. This 1-inch square

PCB model and the thermal resistance vs. PCB area

charts provide the practical thermal resistances for the

following transistor packages:

SOT23: RTHJA = 200 Â°C/W

The thermal resistance can also be obtained from the

transient thermal resistance curve with D = 1 as shown

in Figure 2 and Figure 3.

SOT89: RTHJA = 82.5 Â°C/W

SOT223: RTHJA = 62.5 Â°C/W

Rev. 0.2 9/02

AN47-DS02

▷