MAX746 Maxim, MAX746 Datasheet - Page 13
MAX746
Manufacturer Part Number
MAX746
Description
High-Efficiency / PWM / Step-Down / N-Channel DC-DC Controller
Manufacturer
Maxim
Datasheet
1.MAX746.pdf
(16 pages)
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To ensure the external N-FET is turned on hard, use
logic-level or low-threshold N-FETs. Three important
parameters to note when selecting the N-FET are the
total gate charge (Q
reverse transfer capacitance (C
Q
the gate. Use the typical Q
maximum value is usually grossly overspecified, since
it is a guaranteed limit and not the measured value.
The typical total gate charge should be 50nC or less;
with larger numbers, EXT may not be able to ade-
quately drive the gate. EXT sink/source capability
(I
The two most significant losses contributing to the
N-FET’s power dissipation are I
losses. CCM power dissipation (P
where the duty cycle is approximately V
f
data sheet of the chosen N-FET. In the equation,
r
of temperature. The equation given does not account
for losses incurred by charging and discharging the
gate capacitance, because that energy is dissipated
by the gate-drive circuitry, not the N-FET.
The Standard Application Circuits (Figure 1) use an
8-pin, Si9410DY, surface-mount N-FET that has 0.05Ω
on resistance with a 4.5V V
obtained when the voltage at the source swings between
the supply rails (within a few hundred millivolts).
The MAX746’s high switching frequency demands a
high-speed rectifier. Schottky diodes are recommend-
ed. Ensure that the Schottky diode average current
rating exceeds the maximum load current.
The output filter capacitor C1 should have a low effec-
tive series resistance (ESR), and its capacitance should
remain fairly constant over temperature. This is espe-
cially true when in CCM, since the output filter capaci-
tor and the load form the dominant pole that
stabilizes the voltage loop.
OSC
DS(ON)
EXT
g
P
includes all capacitances associated with charging
D
) is typically 210mA.
= 100kHz, and r
=
External Logic-Level N-FET Selection
(
is assumed constant, but is actually a function
Duty Cycle
__________________________
(
V+
2
______________________________________________________________________________________
) (
) (
C
g
DS(ON)
I
PK
), on resistance (r
RSS
(
2
I
EXT
) (
) (
g
GS
r
and C
I
value for best results; the
DS(ON)
)
Capacitor Selection
PK
2
. Optimum efficiency is
Output Filter Capacitor
RSS
R losses and switching
D
) (
), is approximated by:
High-Efficiency, PWM, Step-Down,
f
).
Diode Selection
RSS
OSC
)
+
)
are given in the
DS(ON)
OUT
N-Channel DC-DC Controller
), and
/V+,
To ensure stability, the minimum capacitance and max-
imum ESR values are:
and,
where GBW = the loop gain-bandwidth product, 15kHz.
Sprague 595D surface-mount solid tantalum capacitors
and Sanyo OS-CON through-hole capacitors are rec-
ommended due to their extremely low ESR. OS-CON
capacitors are particularly useful at low temperatures.
For best results when using other capacitors, increase
the output filter capacitor’s size or use capacitors in
parallel to reduce the ESR.
Bypass OUT with a 0.1µF (C4) capacitor to GND when using
a fixed 5V output (Figures 1a and 1c). With adjustable-output
operation, place C4 between the output voltage and AGND
as close to the IC as possible (Figure 1b).
The circuit load-step response is improved by using a
larger output filter capacitor or by placing a low-cost
bulk capacitor in parallel with the required low-ESR
output filter capacitor. The output voltage sag under a
load step (I
where DMAX is the maximum duty cycle (91% worst
case). The equation assumes an input/output voltage
differential of 2V or more. Table 1 gives measured val-
ues of output voltage sag with a 30mA to 3A load step
for various input voltages and output filter capacitors.
Refer also to the AC Stability with Low Input/Output
Differentials section.
The input bypass capacitor C2 reduces peak currents
drawn from the voltage source, and also reduces the
amount of noise at the voltage source caused by the
MAX746’s fast switching action (this is especially
important when other circuitry is operated from the
same source). The input capacitor ripple current rating
must exceed the RMS input ripple current.
V
SAG
C1
= I
(min)
I
RMS
= _____________________________________
STEP
LOAD
ESR
(
= RMS AC input current
> ______________________________
2
) is approximated by:
C1
) (
(
(
2π
C1
_______________________
< ___________________
√
) (
) (
(
(
GBW
V
V
V
OUT
(
OUT
IN(MIN
I
STEP 2
(
5
) (
) (
(
) (
V
V
Input Bypass Capacitor
) (
V
V
REF
IN
) (
V
IN
OUT
) (
R
REF
SENSE
D
)
- V
L
MAX
)
) (
)
OUT
R
)
SENSE
- V
)
)
OUT
)
)
13
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