NCP4353, NCP4354
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11
is discharged through a fixed load, by R8 and R9 faster than
output voltage on C1.
Once OFFDET pin voltage is lower than V
OFFDETTH
(this
threshold is derived from V
OUT
), OFF mode is detected. In
OFF mode SW1 is switched on to allow I
DRIVEOFF
current,
going through ON/OFF pin (NCP4354B) or DRIVE pin, to
keep switch off primary controller.
A higher sink current on primary FB pin is needed to keep
primary controller FB below the skip level until the OFF
mode is detected on primary side.
Despite output voltage on C1 may go down, the current
I
BIASV
injected into VSNS pin provides the requested offset
(VSNS voltage is higher than V
REF
). Primary IC should
detect OFF mode before VSNS is lower than 90% of V
REF
while I
BIASV
is switched off to reduce consumption.
This offset, defined by R7 and the internal current source,
should be large enough to secure off mode detection of the
primary controller and avoid restart when V
SNS
< V
REF
.
Minimum Output Voltage Detection (Except
NCP4353A)
Minimum output voltage level defines primary controller
restart from OFF mode. It can be set by shared voltage
divider with voltage regulation loop. When VMIN voltage
drops below V
REFM
, OFF mode is ended and primary
controller restarts.
Minimum voltage level is given by Equation 5 for divider
type 1
V
MIN
+ V
REF
R4 ) R5 ) R6
R6
(eq. 5)
and for type 2 by Equation 6.
V
MIN
+ V
REF
R4 ) R5 ) R6
R5 ) R6
(eq. 6)
NCP4353A has no external adjustment and uses the
internal minimum voltage level specified by minimum
falling operation supply voltage.
LED Driver (NCP4354x only)
LED driver is active when VCC is higher than V
CCMIN
and output voltage is in regulation (driver is off in OFF
mode). LED driver consists of an internal power switch
controlled by a PWM modulated logic signal and an external
current limiting resistor R3. LED current can be computed
by Equation 7.
I
LED
+
V
OUT
* V
F_LED
R3
(eq. 7)
PWM modulation is used to increase efficiency of LED.
Operation in OFF Mode Description
Operation waveforms in off mode and transition into OFF
mode with NCP1246 primary controller are shown in
Figure 31.
Figure shows waveforms from the first start (1) of the
convertor. At first, primary controller’s DSS charges VCC
capacitor over the UVLO level (2). When primary V
CC
is
over UVLO level (3), primary controller starts to operate.
VCC capacitor is charged above DSS level from auxiliary
winding, V
OUT
is slowly rising according to primary
controller start up ramp to nominal voltage (4).
Primary FB pin voltage is above regulation range until
V
OUT
is at set level. Once V
OUT
is at set level, the secondary
controller starts to sink current from optocoupler LED’s and
primary FB voltage is stabilized in regulation region. With
nominal output power (without skip mode) OFFDET pin
voltage is higher than V
OFFDETTH
(typically 10% of V
CC
).
After some time, the load current decreases to low level
(5) and primary convertor uses skip mode (6) to keep
regulation of output voltage at set level. The skip mode
consists of few switching cycles followed by missing ones
to provide limited energy by light load. The number of
missing cycles allows regulation for any output power.
While both C1 and C2 are discharged during the missing
cycles, C2 discharge will be faster than C1 without output
current, V
OFFDET
drops below V
OFFDETTH
and OFF mode
is detected (7). This situation is shown in Figure 30 in detail.
When OFF mode is detected, internal pull−up current
I
BIASV
is switch on (7), VSNS voltage increases (due to
I
BIASV
) and voltage amplifier sinks full current to keep
primary FB voltage below skip level until OFF mode is
detected by the primary side controller (8). Current into
ONOFF pin or DRIVE pin begins to flow at the same time,
when entering into OFF mode (7). When OFF mode is
detected by primary side controller (8a), primary FB
injected current decreases to a lower level to reduce overall
power consumption. Optocoupler current, can also be
reduced from that time to keep the level below restart level.
Secondary side controller decreases optocoupler current
(voltage transconductance amplifier stops to sink current)
when VSNS voltage drops below V
REF
(9) and I
BIASV
is
also switch off when V
SNS
is lower than 90% of V
REF
to
reduce overall consumption. This point is defined by I
BIASV
current, R6, R4 and R5 resistors and discharging time of
output capacitor C1. Discharging of C1 continues (10) until
output voltage drops below level set by voltage divider at
VMIN pin (except NCP4353A where minimum V
OUT
is
defined only by VCC UVLO) (11). ONOFF current stops
and thanks to internal pull−up, the primary FB voltage rises
above restart level (12) and primary controller starts
switching (13). Output capacitor C1 is recharged (14) to set
voltage. If there is still light load condition primary
controller goes to skip mode (15) again and after some time
secondary controller detects OFF mode by very light or no
load condition (16) and whole cycle is repeated.
Fast Restart From OFF Mode
The IC ends OFF mode when a load is connected to the
output and V
OUT
is discharged to V
MIN
level. There exists
another connection that allows transition to normal mode
faster without waiting some time for V
OUT
to discharge to
V
MIN
. This schematic is shown at Figure 32. The basic idea
is that C3 is discharged by the IC faster than C1 by output