MAX5015ESA+ Maxim Integrated Products, MAX5015ESA+ Datasheet - Page 10

IC CNTRLR PWM CRNT MD 8-SOIC

MAX5015ESA+

Manufacturer Part Number
MAX5015ESA+
Description
IC CNTRLR PWM CRNT MD 8-SOIC
Manufacturer
Maxim Integrated Products
Datasheet

Specifications of MAX5015ESA+

Pwm Type
Current Mode
Number Of Outputs
1
Frequency - Max
275kHz
Duty Cycle
50%
Voltage - Supply
18 V ~ 110 V
Buck
No
Boost
No
Flyback
No
Inverting
No
Doubler
No
Divider
No
Cuk
No
Isolated
Yes
Operating Temperature
-40°C ~ 85°C
Package / Case
8-SOIC (3.9mm Width)
Frequency-max
275kHz
Duty Cycle (max)
50 %
Output Current
1000 mA
Mounting Style
SMD/SMT
Switching Frequency
275 KHz
Maximum Operating Temperature
+ 85 C
Minimum Operating Temperature
- 40 C
Synchronous Pin
No
Topology
Flyback, Forward
Lead Free Status / RoHS Status
Lead free / RoHS Compliant
where C
Operation begins when V
When soft-start has completed, V
to 2.4V, the internal voltage reference. Pull V
below 0.25V to disable the controller.
Undervoltage lockout shuts down the controller when
V
erence remain on during shutdown.
The current-sense (CS) comparator and its associated
logic limit the peak current through the MOSFET.
Current is sensed at CS as a voltage across a sense
resistor between the source of the MOSFET and GND.
To reduce switching noise, connect CS to the external
MOSFET source through a 100Ω resistor or an RC low-
pass filter (Figures 2, 3). Select the current-sense resis-
tor, R
where I
current.
When V
The propagation delay from the time the switch current
reaches the trip level to the driver turn-off time is 170ns.
An internal 275kHz oscillator determines the switching
frequency of the controller. At the beginning of each
cycle, NDRV switches the N-channel MOSFET on.
NDRV switches the external MOSFET off after the maxi-
mum duty cycle has been reached, regardless of the
feedback.
The MAX5014 uses an internal ramp generator for
slope compensation. The internal ramp signal is reset
at the beginning of each cycle and slews at 26mV/µs.
The PWM comparator uses the instantaneous current,
the error voltage, the internal reference, and the slope
compensation (MAX5014 only) to determine when to
switch the N-channel MOSFET off. In normal operation
the N-channel MOSFET turns off when:
where I
MOSFET, V
Current-Mode PWM Controllers with Integrated
Startup Circuit for Isolated Power Supplies
10
PWM Comparator and Slope Compensation
CC
is less than 6.6V. The regulators for V+ and the ref-
______________________________________________________________________________________
SENSE
I
PRIMARY
PRIMARY
SS
LimPrimary
CS
is the soft-start capacitor as shown in Figure 2.
> 465mV, the power MOSFET switches off.
according to the following equation:
REF
R
t
SENSE
×
startup
R
is the current through the N-channel
is the 2.4V internal reference and
SENSE
is the maximum peak primary-side
Current-Sense Comparator
= 0 465
=
0 45
.
>
.
SS_SHDN
V
OPTO
ms
nF
/ V
I
LimPrimary
×
- V
C
SS_SHDN
ss
REF
ramps above 0.6V.
- VS
is regulated
COMP
SS_SHDN
V
26mV/µs (MAX5014 only). When using the MAX5014 in
a forward-converter configuration the following condi-
tion must be met to avoid control-loop subharmonic
oscillations:
where k = 0.75 to 1, and N
turns on the secondary and primary side of the trans-
former, respectively. L is the output filter inductor. This
makes the output inductor current downslope as refer-
enced across R
tion. The controller responds to transients within one
cycle when this condition is met.
NDRV drives an N-channel MOSFET. NDRV sources
and sinks large transient currents to charge and dis-
charge the MOSFET gate. To support such switching
transients, bypass V
average current as a result of switching the MOSFET is
the product of the total gate charge and the operating
frequency. It is this current plus the DC quiescent cur-
rent that determines the total operating current.
The following is a general procedure for designing a
forward converter (Figure 2) using the MAX5015.
The circuit in Figure 2 was designed as follows:
1) 36V ≤ V
2) To set the output voltage calculate the values of
SCOMP
1) Determine the requirements.
2) Set the output voltage.
3) Calculate the transformer primary to secondary
4) Calculate the reset to primary winding turns ratio.
5) Calculate the tertiary to primary winding turns
6) Calculate the current-sense resistor value.
7) Calculate the output inductor value.
8) Select the output capacitor.
50mV
resistors R1 and R2 according to the following
equation:
winding turns ratio.
ratio.
is a ramp function starting at 0 and slewing at
IN
N
N
≤ 72V, V
S
P
N-Channel MOSFET Gate Driver
Applications Information
×
SENSE
k R
×
CC
OUT
SENSE
equal to the slope compensa-
with a ceramic capacitor. The
L
= 5V, I
S
×
and N
V
OUT
OUT
Design Example
P
=
are the number of
26
= 10A, V
mV
/
µ
s
RIPPLE

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