MAX15000AEUB+ Maxim Integrated Products, MAX15000AEUB+ Datasheet - Page 9

MAX15000AEUB+

Manufacturer Part Number

MAX15000AEUB+

Description

IC CNTRLR PWM CURRENT MD 10UMAX

Manufacturer

Maxim Integrated Products

Datasheet

1.MAX15000AEUBT.pdf (18 pages)

Specifications of MAX15000AEUB+

Pwm Type

Current Mode

Number Of Outputs

Frequency - Max

2.5MHz

Duty Cycle

50%

Voltage - Supply

23.6 V ~ 30 V

Buck

Boost

Yes

Flyback

Yes

Inverting

Doubler

Divider

Cuk

Isolated

Yes

Operating Temperature

-40°C ~ 85°C

Package / Case

10-MSOP, Micro10™, 10-uMAX, 10-uSOP

Frequency-max

2.5MHz

Duty Cycle (max)

50 %

Output Current

1000 mA

Mounting Style

SMD/SMT

Switching Frequency

25 KHz to 625 KHz

Maximum Operating Temperature

+ 85 C

Minimum Operating Temperature

- 40 C

Synchronous Pin

Topology

Boost

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

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The advantages of current-mode control over voltage-

mode control are twofold. First, there is the feed-for-

ward characteristic brought on by the controller’s

ability to adjust for variations in the input voltage on a

cycle-by-cycle basis. Secondly, the stability require-

ments of the current-mode controller are reduced to

that of a single-pole system unlike the double pole in

voltage-mode control.

The MAX15000/MAX15001 use a current-mode control

loop where the output of the error amplifier (COMP) is

compared to the current-sense voltage at CS. When the

current-sense signal is lower than the noninverting

input of the PWM comparator, the output of the CPWM

comparator is low and the switch is turned on at each

clock pulse. When the current-sense signal is higher than

the inverting input of the CPWM, the output of the CPWM

comparator goes high and the switch is turned off.

The MAX15000/MAX15001 provide a UVLO/EN input.

The threshold for UVLO is 1.23V with 60mV hysteresis.

Before any operation can commence, the voltage on

UVLO/EN has to exceed 1.23V. The UVLO circuit keeps

the CPWM comparator, ILIM comparator, oscillator,

and output driver shut down to reduce current con-

sumption (see the Functional Diagram).

Use this UVLO/EN input to program the input-supply

start voltage. For example, a reasonable start voltage

for a 36V to 72V telecom range is usually 34V.

Calculate the resistor-divider values, R2 and R3 (see

Figure 1) by using the following formulas:

where I

and V

power supply must start. The value of R3 is calculated

to minimize the voltage-drop error across R2 as a result

of the input bias current of the UVLO/EN input.

is the value of the input-supply voltage where the

ULR2

UVLO

is the UVLO/EN wake-up threshold (1.23V).

is the UVLO/EN input current (50nA max),

≅

_______________________________________________________________________________________

500

Current-Mode Control Loop

UVLO IN

Undervoltage Lockout

−

ULR

Programmable Switching Frequency

Current-Mode PWM Controllers with

(

ULR

−

ULR

)

In addition to the externally programmable UVLO func-

tion offered in both the MAX15000 and MAX15001, the

MAX15000 includes an internal bootstrap UVLO that is

very useful when designing high-voltage power sup-

plies (see the Functional Diagram). This allows the

device to bootstrap itself during initial power-up. The

MAX15000 attempts to start when V

bootstrap UVLO threshold of 21.6V. During startup, the

UVLO circuit keeps the CPWM comparator, ILIM com-

parator, oscillator, and output driver shut down to

reduce current consumption. Once V

the UVLO circuit turns on the CPWM and ILIM com-

parators, the oscillator, and allows the output driver to

switch. If V

down the CPWM comparator, ILIM comparator, oscilla-

tor, and output driver returning the MAX15000 to the

low-current startup mode.

The MAX15001 starts up when the voltage at IN

exceeds 9.5V and the UVLO/EN input is greater than

1.23V. However, the MAX15000 requires that, in addi-

tion to meeting the specified startup conditions for the

MAX15001, the voltage at IN exceeds the bootstrap

UVLO threshold of 21.6V.

For the MAX15000, the voltage at IN is normally derived

from a tertiary winding of the transformer. However, at

startup there is no energy being delivered through the

transformer, hence, a special bootstrap sequence is

required. Figure 2 shows the voltages at IN and V

during startup. Initially, both V

the line voltage is applied, C1 charges through the

startup resistor, R1, to an intermediate voltage. At this

point, the internal regulator begins charging C2 (see

Figure 1). Only 50µA of the current supplied through R1

is used by the MAX15000, the remaining input current

charges C1 and C2. The charging of C2 stops when

the V

voltage across C1 continues rising until it reaches the

wake-up level of 21.6V. Once V

strap UVLO threshold, NDRV begins switching the

MOSFET and transfers energy to the secondary and

tertiary outputs. If the voltage on the tertiary output

builds to higher than 9.74V (the bootstrap UVLO lower

voltage reaches approximately 9.5V, while the

drops below 1.17V, the UVLO circuit shuts

MAX15000 Bootstrap UVLO

Startup Operation

and V

exceeds the boot-

reaches 21.6V,

exceeds the

are 0V. After

MAX15000AEUB+ Maxim Integrated Products, MAX15000AEUB+ Datasheet - Page 9

MAX15000AEUB+

Specifications of MAX15000AEUB+

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