LTC1553L_15 Datasheet, PDF(17/20 Page) Linear Technology – 5-Bit Programmable Synchronous Switching Regulator Controller

English

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

LTC1553L_15 Datasheet, PDF (17/20 Pages) Linear Technology – 5-Bit Programmable Synchronous Switching Regulator Controller

◁

LTC1553L

APPLICATIONS INFORMATION

Table 6 shows the suggested compensation components

for 5V input applications based on the inductor and output

capacitor values. The values were calculated using mul-

tiple paralleled 330ÂµF AVX TPS series surface mount

tantalum capacitors as the output capacitor. The optimum

component values might deviate from the suggested

values slightly because of board layout and operating

condition differences.

An alternate output capacitor is the Sanyo MV-GX series.

Using multiple parallel 1500ÂµF Sanyo MV-GX capacitors

for the output capacitor, Table 7 shows the suggested

compensation component value for a 5V input application

based on the inductor and output capacitor values.

Table 7. Suggested Compensation Network for 5V Input

Application Using Multiple Paralleled 1500ÂµF SANYO MV-GX

Output Capacitors

LO (ÂµH)

CO (ÂµF)

4500

RC (kâ¦)

4.3

CC (ÂµF)

0.022

C1 (pF)

270

6000

5.6

0.0047

220

9000

8.2

0.01

150

2.7

4500

0.01

100

2.7

6000

0.01

2.7

9000

0.01

5.6

4500

0.01

5.6

6000

0.0047

5.6

9000

0.0047

VID0 to VID4, PWRGD and FAULT

The digital inputs (VID0 to VID4) program the internal DAC

which in turn controls the output voltage. These digital

input controls are intended to be static and are not

designed for high speed switching. Forcing VOUT to step

from a high to a low voltage by changing the VIDn pins

quickly can cause FAULT to trip.

Figure 9 shows the relationship between the VOUT voltage,

PWRGD and FAULT. To prevent PWRGD from interrupting

the CPU unnecessarily, the LTC1553L has a built-in tPWRBAD

delay to prevent noise at the SENSE pin from toggling

PWRGD. The internal time delay is designed to take about

500Âµs for PWRGD to go low and 1ms for it to recover.

Once PWRGD goes low, the internal circuitry watches for

the output voltage to exceed 115% of the rated voltage. If

this happens, FAULT will be triggered. Once FAULT is

triggered, G1 and G2 will be forced low immediately and

the LTC1553L will remain in this state until VCC power

supply is recycled or OUTEN is toggled.

15%

RATED VOUT

â5%

tPWRBAD

PWRGD

VOUT

tPWRGD

tFAULT

FAULT

Figure 9. PWRGD and FAULT

1553L F09

LAYOUT CONSIDERATIONS

When laying out the printed circuit board, the following

checklist should be used to ensure proper operation of the

LTC1553L. These items are also illustrated graphically in

the layout diagram of Figure 10. The thicker lines show the

high current paths. Note that at 10A current levels or

above, current density in the PC board itself is a serious

concern. Traces carrying high current should be as wide

as possible. For example, a PCB fabricated with 2oz

copper requires a minimum trace width of 0.15" to

carry 10A.

1. In general, layout should begin with the location of the

power devices. Be sure to orient the power circuitry so

that a clean power flow path is achieved. Conductor

widths should be maximized and lengths minimized.

After you are satisfied with the power path, the control

circuitry should be laid out. It is much easier to find

routes for the relatively small traces in the control

circuits than it is to find circuitous routes for high

current paths.

2. The GND and SGND pins should be shorted right at the

LTC1553L. This helps to minimize internal ground

disturbances in the LTC1553L and prevents differences

in ground potential from disrupting internal circuit

operation. This connection should then tie into the

▷