MAX774(2002) Ver la hoja de datos (PDF) - Maxim Integrated
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MAX774
(Rev.:2002)
(Rev.:2002)
Maxim Integrated
MAX774 Datasheet PDF : 16 Pages
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-5V/-12V/-15V or Adjustable, High-Efficiency,
Low IQ Inverting DC-to-DC Controllers
VIN
C1
150µF
1 OUT
C2
V+ 5
0.1µF
MAX774
3 SHDN MAX775 CS 6
2 FB
MAX776 7
EXT
R1
0.07Ω
Q1
Si9435
P
4 REF
GND
C3
8
0.1µF
L1
22µH
1N5822/
MBR340
VOUT
C4*
* MAX774 = 330µF, 10V
MAX775, MAX776 = 120µF, 20V
PRODUCT
MAX774
MAX775
MAX776
OUTPUT
VOLTAGE (V)
-5
-12
-15
INPUT
VOLTAGE (V)
3 to 15
3 to 8
3 to 5
OUTPUT
CURRENT (A)
1
0.5
0.4
NOTE: Si9435 HAS VGS OF 20V MAX
Figure 2. Bootstrapped Connection Using Fixed Output
Voltages
VIN
C1
150µF
R2
C2
0.1µF
R1
C3
0.1µF
1 OUT
V+ 5
R3
3 SHDN MAX774
0.07Ω
2 FB
MAX775 CS 6
MAX776 EXT 7
Q1
Si9435
P
VOUT
4 REF
GND
1N5822/
8
L1 MBR340
22µH
C4*
* MAX774 = 330µF, 10V
MAX775, MAX776 = 120µF, 20V
Figure 3. Bootstrapped Connection Using External Feedback
Resistors
the current limit for the first two pulses is set to one-half
the peak current limit. If those pulses bring the output
voltage into regulation, the voltage comparator keeps
the MOSFET off, and the current limit remains at one-half
the peak current limit. If the output voltage is out of
regulation after two consecutive pulses, the current limit
VIN
C1
150µF
R2
C2
0.1µF
1 OUT
V+ 5
R3
3 SHDN MAX774
0.07Ω
2 FB
R1
MAX775 CS 6
MAX776 7
EXT
Q1
Si9435
P
VOUT
4 REF
GND
C3
8
0.1µF
L1
22µH
1N5822/
MBR340
C4*
* MAX774 = 330µF, 10V
MAX775, MAX776 = 120µF, 20V
Figure 4. Nonbootstrapped Operation (VIN > 4.5V)
for the next pulse will equal the full current limit.
With heavy loads, the MOSFET first switches twice at
one-half the peak current value. Subsequently, it stays
on until the switch current reaches the full current limit,
and then turns off. After it is off for 2.3µs, the MOSFET
switches on once more, and remains on until the switch
current again reaches its limit. This cycle repeats until
the output is in regulation.
A benefit of this control scheme is that it is highly effi-
cient over a wide range of input/output ratios and load
currents. Additionally, PFM converters do not operate
with constant-frequency switching, and have relaxed
stability criterion (unlike PWM converters). As a result,
their external components require smaller values.
With PFM converters, the output voltage ripple is not
concentrated at the oscillator frequency (as it is with
PWM converters). For applications where the ripple fre-
quency is important, the PWM control scheme must be
used. However, for many other applications, the smaller
capacitors and lower supply current of the PFM control
scheme make it the better choice. The output voltage
ripple with the MAX774/MAX775/MAX776 can be held
quite low. For example, using the circuit of Figure 2,
only 100mV of output ripple is produced when generat-
ing a -5V at 1A output from a +5V input.
Bootstrapped vs.
Nonbootstrapped Operation
Figures 2 and 3 are the standard application circuits
for bootstrapped mode, and Figure 4 is the circuit for
nonbootstrapped mode. Since EXT is powered by OUT,
using bootstrapped or nonbootstrapped mode will
directly affect the gate drive to the FET. EXT swings
from V+ to VOUT. In bootstrapped operation, OUT is
10 ______________________________________________________________________________________
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