max5059auit Maxim Integrated Products, Inc., max5059auit Datasheet - Page 12

max5059auit

Manufacturer Part Number

max5059auit

Description

Parallelable, Secondary-side Synchronous Rectifier Driver And Feedback-generator Controller Ics

Manufacturer

Maxim Integrated Products, Inc.

Datasheet

1.MAX5059AUIT.pdf (25 pages)

Current page: 12 of 25
Download datasheet (348Kb)

Parallelable Secondary-Side Synchronous Rectifier

Driver and Feedback-Generator Controller ICs

The MAX5058/MAX5059 enable the design of high-effi-

ciency, isolated power supplies using synchronous rec-

tification on the secondary side. These devices

commutate the secondary-side MOSFETs by providing

a clean gate-drive signal that is synchronized to the

power MOSFET switching in the primary side of the iso-

lation transformer. Once fully enhanced, the secondary-

side MOSFETs have very low on-resistance, producing

a voltage drop much lower than Schottky diodes, result-

ing in much higher efficiencies. Simultaneous conduc-

tion of the synchronous rectifier MOSFETs is avoided by

having a look-ahead signal before the primary

MOSFETs turn on. This eliminates large current spikes

from a shorted transformer secondary.

The MAX5058 has a 5V internal gate-drive voltage reg-

ulator that can be used with logic-level MOSFETs. The

MAX5059 has a 10V internal gate-drive voltage regula-

tor that can be used with high-gate-voltage MOSFETs.

In addition to the gate drivers, there are blocks that

make the MAX5058/MAX5059 complete secondary-

side solutions. These blocks are as follows:

The linear regulators in the MAX5058/MAX5059 provide

power for the internal circuitry, as well as power for run-

ning the external synchronous MOSFETs. Design is sim-

plified by deriving the power from the secondary

winding before the output-filter inductor. The peak volt-

age at the secondary is at least twice the output volt-

age, yielding more than 7V peak even for output

voltages down to 3.3V. Use a diode and a capacitor to

rectify and filter the voltage before applying it to V+ (see

D6 and C32 in the Typical Application Circuit). The

input for the regulator is V+ and the output is V

Connect VDR to V

driver’s QREC and QSYNC. For logic-level MOSFETs,

use the MAX5058. For conventional MOSFETs that

require 10V to be fully enhanced, use the MAX5059.

The V+ input voltage range is from +4.5V to +28V.

Supply enough current to this input to satisfy the quies-

• Regulator and thermal-management block

• Buffer input and gate-driver block

• Reference-current block

• Error-amplifier block

• Margining block

• Remote-sense amplifier block

• Current-share block

______________________________________________________________________________________

Regulators and Thermal Management

REG

Detailed Description

to provide the supply for the gate

REG

cent supply current of the MAX5058/MAX5059, as well

as the current for the MOSFET drivers. Estimate the total

required supply current by using the following formula:

where I

and Q

N3 and N4 in the Typical Application Circuit. f

switching frequency and I

the part. Use high-quality ceramic capacitors to bypass

V+ and V

for bypassing switching currents generated by the dri-

vers when driving the chosen MOSFETs. Connect at

least a 1µF ceramic capacitor at the output of the regu-

lator V

The MAX5058/MAX5059 have an exposed pad at the

back of the package to enable heatsinking directly to a

ground plane. When soldered to a 1in

these devices are able to dissipate approximately 1.9W

at +70°C ambient temperature. Connect the exposed

pad to the GND.

In addition to the regulators, this block contains a ther-

mal-shutdown circuit that shuts down the gate drivers if

the die temperature exceeds +160°C. This is a last

resort shutdown mechanism. The trigger of this shut-

down mechanism must be avoided. Turning off the

secondary synchronous rectifier drivers in this manner

while the output carries the full load current causes the

current to be diverted to the lossy external diodes or

body diodes of the MOSFETs. This, in most cases,

leads to rectifier failure due to power dissipation. To

prevent this, make use of the TSF output (temperature

warning flag). TSF is an open-drain output that gets

asserted when the die temperature exceeds +125°C,

well before the actual thermal shutdown at +160°C. An

optocoupler connected from V

provide a means for shutting down the switching at the

primary side, thus avoiding catastrophic failure.

The MAX5058/MAX5059 drive external N-channel

MOSFETs at QSYNC and QREC. The QSYNC output

drives the gate of the freewheeling MOSFET N4 in the

Typical Application Circuit. The QREC output drives the

gate of the rectifying MOSFET N3 in the Typical

Application Circuit. Each gate-driver output is capable

of sinking and sourcing up to 2A peak current,

enabling the MAX5058/MAX5059 to drive high-gate-

charge MOSFETs.

Buffer Input (BUFIN) and MOSFET Drivers

REG

V+

, Q

REG

is the current that must be supplied into V+

for stability.

. Use additional capacitance as required

are the total gate charges of MOSFETs

is the switching current of

(

REG

to the TSF pin can

copper island,

)

is the

max5059auit Maxim Integrated Products, Inc., max5059auit Datasheet - Page 12

max5059auit

Related parts for max5059auit