MAX17480GTL+ Maxim Integrated Products, MAX17480GTL+ Datasheet - Page 43

MAX17480GTL+

Manufacturer Part Number

MAX17480GTL+

Description

IC CTRLR SERIAL VID 40-TQFN

Manufacturer

Maxim Integrated Products

Datasheet

1.MAX17480GTLT.pdf (48 pages)

Specifications of MAX17480GTL+

Applications

Processor

Current - Supply

5mA

Voltage - Supply

4.5 V ~ 5.5 V

Operating Temperature

-40°C ~ 105°C

Mounting Type

Surface Mount

Package / Case

40-TQFN Exposed Pad

Output Voltage Range

- 10 V to + 10 V

Input Voltage Range

4 V to 26 V

Input Current

5 mA

Power Dissipation

1778 mW

Operating Temperature Range

- 40 C to + 105 C

Mounting Style

SMD/SMT

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

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The capacitance value required is determined primarily

by the stability requirements. However, the soar and

sag calculations are still provided here for reference.

Low inductor values allow the inductor current to slew

faster, replenishing charge removed from or added to

the output filter capacitors by a sudden load step.

Therefore, the amount of output soar and sag when the

load is applied or removed is a function of the output

voltage and inductor value. The soar and sag voltages

are calculated as:

where D

SMPS as listed in the Electrical Characteristics table,

OSC pin, and ∆t equals V

PWM mode, or L x I

skipping mode.

When using low-capacity ceramic filter capacitors,

capacitor size is usually determined by the capacity

needed to prevent V

load transients. Generally, once enough capacitance is

added to meet the overshoot requirement, undershoot at

the rising load edge is no longer a problem.

The input capacitor must meet the ripple-current require-

ment (I

requirements can be determined by the following equation:

The worst-case RMS current requirement occurs when

operating with V

equation simplifies to I

For most applications, nontantalum chemistries

(ceramic, aluminum, or OS-CON) are preferred due to

their resistance to inrush surge currents typical of sys-

tems with a mechanical switch or connector in series

with the input. The MAX17480 NB regulator is operated

as the second stage of a two-stage power-conversion

system. Tantalum input capacitors are acceptable.

Choose an input capacitor that exhibits less than 10°C

temperature rise at the RMS input current for optimal

circuit longevity.

SW3

SAG

is the NB switching period programmed by the

RMS

MAX

OUT

) imposed by the switching currents. The I

(

∆

is the maximum duty cycle of the NB

(

L L OAD MAX

⎛

⎜

⎝

IN3

SOAR

LOAD

______________________________________________________________________________________

(

SOAR

LX3MIN

= 2V

MAX

RMS

⎞

⎟

⎠

(

)

∆

NB Input Capacitor Selection

OUT3

OUT

−

from causing problems during

LOAD MAX

= 0.5 x I

/(V

OUT

. At this point, the above

(

)

- V

(

OUT

x t

∆

LOAD3

)

OUT

)

L L OAD MAX

−

) when in pulse-

when in forced-

OUT

(

OUT

AMD 2-/3-Output Mobile Serial

)

(

)

−

RMS

∆

)

Voltage positioning dynamically lowers the output volt-

age in response to the load current, reducing the out-

put capacitance and processor’s power-dissipation

requirements. For NB, the load line is generated by

sensing the inductor current through the high-side

MOSFET on-resistance (R

preset to -5.5mV/A (typ). This guarantees the output

voltage to stay in the static regulation window over the

maximum load conditions per AMD specifications. See

Table 6 for full-load voltage droop according to differ-

ent ILIM3 settings.

The voltage-positioned load-line of the NB SMPS also

provides the AC ripple voltage required for stability. To

maintain stability, the output capacitive ripple must be

kept smaller than the internal AC ripple voltage. Hence,

a minimum NB output capacitance is required as calcu-

lated below:

where R

Electrical Characteristics table, and f

switching frequency programmed by the OSC pin.

The MAX17480 is a receive-only device. The 2-wire seri-

al bus (pins SVC and SVD) is designed to attach on a

low-voltage I

the CPU directly drives the bus at a speed of 3.4MHz.

The CPU has a push-pull output driving to the V

voltage level. External pullup resistors are not required.

When not used in the specific AMD application, the ser-

ial interface can be driven to as high as 2.5V, and can

operate at the lower speeds (100kHz, 400kHz, or

1.7MHz). At lower clock speeds, external pullup resis-

tors can be used for open-drain outputs. Connect both

SVC and SVD lines to V

resistors. Calculate the required value of the pullup

resistors using:

where t

the clock period. C

The MAX17480 is compatible with the standard SVI inter-

face protocol as defined in the following subsections.

Figure 12 shows the SVI bus START, STOP, and data

change conditions.

OUT

is the rise time, and should be less than 10% of

DROOP3(MIN)

SVI Applications Information

C-like bus. In the AMD mobile application,

NB Steady-State Voltage Positioning

BUS

C Bus-Compatible Interface

NB Transient Droop and Stability

PULLUP

VID Controller

is the total capacitance on the bus.

DDIO

is 4mV/A as defined in the

DROOP MIN

ON(NH3)

≤

through individual pullup

BUS

(

), and is internally

)

⎛

⎝ ⎜

SW3

OUT

is the NB

⎞

⎠ ⎟

DDIO

MAX17480GTL+ Maxim Integrated Products, MAX17480GTL+ Datasheet - Page 43

MAX17480GTL+

Specifications of MAX17480GTL+

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