MAX6841IUKD4+T Maxim Integrated, MAX6841IUKD4+T Datasheet - Page 14

MAX6841IUKD4+T

Manufacturer Part Number

MAX6841IUKD4+T

Description

Supervisory Circuits

Manufacturer

Maxim Integrated

Series

MAX6841, MAX6842, MAX6843, MAX6844, MAX6845r

Datasheet

1.MAX6841IUKD4T.pdf (24 pages)

Specifications of MAX6841IUKD4+T

Number Of Voltages Monitored

Monitored Voltage

0.9 V to 1.5 V

Undervoltage Threshold

1.35 V

Overvoltage Threshold

1.425 V

Output Type

Active High, Active Low, Push-Pull

Manual Reset

Resettable

Watchdog

No Watchdog

Battery Backup Switching

No Backup

Power-up Reset Delay (typ)

2240 ms

Supply Voltage - Max

1.8 V

Maximum Operating Temperature

+ 85 C

Mounting Style

SMD/SMT

Package / Case

SOT-23

Chip Enable Signals

Maximum Power Dissipation

571 mW

Minimum Operating Temperature

- 40 C

Power Fail Detection

Supply Current (typ)

8.1 uA

Supply Voltage - Min

0.75 V

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Two-Phase Desktop CPU Core Supply

Controllers with Controlled VID Change

EMF causes LX to go high earlier than normal, extend-

ing the on-time by a period equal to the DH rising

dead-time.

When the controller operates in continuous mode, the

dead-time is no longer a factor, and the actual switch-

ing frequency is:

where V

in the inductor discharge path, including the synchro-

nous rectifier, inductor, and PC board resistances;

path, including the high-side MOSFET, inductor, and

PC board resistances.

The two phases of the MAX1937/MAX1938/MAX1939

operate 180° out-of-phase to reduce input filtering

requirements, reduce electromagnetic interference

(EMI), and improve efficiency. This effectively lowers

cost and saves board space, making the MAX1937/

MAX1938/MAX1939 ideal for cost-sensitive applica-

tions.

With dual synchronized out-of-phase operation, the

MAX1937/MAX1938/MAX1939s’ high-side MOSFETs turn

on 180° out-of-phase. The instantaneous input current

peaks of both regulators do not overlap, resulting in

reduced input voltage ripple and RMS ripple current.

This reduces the input capacitance requirement, allowing

fewer or less expensive capacitors, and reduces shield-

ing requirements for EMI. The 180° out-of-phase wave-

forms are shown in the Typical Operating Characteristics.

Each phase operates with a 250kHz switching frequen-

cy. Since the two regulators operate 180° out-of-phase,

an effective switching of 500kHz is seen at the input

and output. In addition to being at a higher frequency

(compared to a single-phase regulator), both the input

and output ripple have lower amplitude.

To minimize the crosstalk noise in the two phases, the

maximum duty cycle of the MAX1937/MAX1938/

MAX1939 is less than 50%. To provide a fast transient

response, these devices have a phase-overlap mode

that allows the two phases to operate in phase when a

heavy-load transient is detected. In-phase operation

continues until the output voltage returns to the nominal

output voltage regulation value.

DROP2

______________________________________________________________________________________

DROP1

is the sum of the resistances in the charging

Synchronized 2-Phase Operation

is the sum of the parasitic voltage drops

(

VCC

OUT

DROP

−

Phase Overlap

DROP

)

Once regulation is achieved, the controller returns to

180° out-of-phase operation. A minimum current-adap-

tive phase-selection algorithm is used to determine which

phase is used to start the first out-of-phase cycle. Once

the output voltage returns to the nominal output voltage

regulation value, the subsequent cycle starts with the

phase that has the lowest inductor current. For example,

if the current-sense inputs indicate that phase 2 has

lower inductor current than phase 1, the controller turns

on phase 2’s high-side MOSFET first when returning to

normal operation.

The MAX1937/MAX1938/MAX1939 use differential

sensing of the output voltage to achieve the highest

possible accuracy of the output voltage. This allows the

error comparator to sense the actual voltage at the

load, so that the controller can compensate for losses

in the power output and ground lines.

FB and GNDS are used for the differential output voltage

sensing. The controller triggers the next cycle (turn on

the high-side MOSFET) when the error comparator is low

mum off-time one-shot has timed out.

Traces from FB and GNDS should be routed close to

each other and as far away as possible from sources of

noise (such as the inductors and high di/dt traces). If

noise on these connections cannot be prevented, then

use RC filters. To filter FB, connect a 100Ω series resistor

from the positive sense trace to FB, and connect a

1000pF capacitor from FB to GND right at the FB pin. For

GNDS, connect a 100Ω series resistor from the negative

sense trace to GNDS, and connect a 1000pF capacitor

from GNDS to GND at the GNDS pin.

For VRM applications, connect a 10kΩ resistor from FB

to the output locally (on the VRM board), and connect a

10kΩ resistor from GNDS to PGND locally (on the VRM

board). FB and GNDS also connect to the output at the

load (off the VRM board, at the microprocessor). This

provides the benefits of differential output voltage sens-

ing mentioned above and the safety of regulating the

output voltage on the board in case the external sense

connections get disconnected.

A 6V linear regulator (U2) is used to step down the

main supply. The output of this linear regulator is con-

nected to VLG to provide power for the low-side gate

drive and bootstrap circuit. Using 6V for this supply

improves efficiency by providing a stronger gate drive

than a 5V supply. To reduce switching noise on VLG,

is below the current-limit threshold, and the mini-

- V

Differential Voltage Sensing and Error

GNDS

is less than the VID regulation voltage),

External Linear Regulator

Comparator

MAX6841IUKD4+T Maxim Integrated, MAX6841IUKD4+T Datasheet - Page 14

MAX6841IUKD4+T

Specifications of MAX6841IUKD4+T

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