POWERINT PFS7327H

PFS7323-7329
HiperPFS-2 Family
™
High Power PFC Controller with Integrated
High-Voltage MOSFET and Qspeed™ Diode
Key Benefits
•
Output Power Table
Highly integrated for smallest boost PFC form factor
Integrated controller and MOSFET in all package options
• Ultra-low reverse recovery loss diode (Qspeed) included in
extended eSIP™ package option
• Lossless internal current sense reduces component count
and system losses
• EN61000-3-2 Class C and D compliant
Packaging optimized for high volume production
• Exposed pad connected to GROUND pin (CoolPAD)
• Eliminates insulating pad/heat-spreader
Enhanced features
• Programmable power good (PG) signal
• User selectable power limit: Enables device swapping in a
given design to optimize efficiency/cost
• Integrated non-linear amplifier for fast output OV and UV
protection
High efficiency and power factor across load range
• >95% efficiency from 10% load to full load
• <200 mW no-load consumption at 230 VAC in remote off-state
• Light load PF >0.9 at 20% load on optimized designs >200 W
• PF >0.95 at 50% load
• Enables 80+ Platinum designs
Frequency adjusted over line voltage and each line cycle
• Spread-spectrum across >60 kHz window simplifies EMI
filtering requirements
• Lower boost inductance
Provides up to 425 W peak output power
• >425 W peak power in power limit voltage regulation mode
eSIP-16 Package
•
•
•
•
•
•
Product
PFS7323L
110 W
120 W
PFS7324L
130 W
150 W
PFS7325L
185 W
205 W
PFS7326H
230 W
260 W
PFS7327H
290 W
320 W
PFS7328H
350 W
385 W
PFS7329H
380 W
425 W
Table 1.
•
•
Full Mode
(R = 24.9 kW)
Output Power Table (See Table 2 on page 11 for Maximum Continuous
Output Power Ratings.)
Protection features include: UV, OV, OTP, brown-in/out,
cycle-by-cycle current limit and power limiting for overload
protection
Halogen free and RoHS compliant
Applications
• PC
• Printer
• LCD TV • Video game consoles D
Peak Output Power Rating
Maximum Continuous
Output Power Rating at
90 VAC (in Full Mode)
•
High-power adaptors
High-power LED lighting
• Industrial and appliance
• Generic PFC converters
•
K
+
PG
VCC
VCC
CONTROL
AC
IN
FB
C
HiperPFS-2
DC
OUT
PGT
S
Figure 1.
www.powerint.com V
Typical Application Schematic.
G
R
PI-6691-050313
June 2013
PFS7323-7329
Description
The HiperPFS-2 device family members reach a very high level
of integration including a continuous conduction mode (CCM)
boost PFC controller, gate driver, ultra-low reverse recovery
(Qspeed) diode (eeSIP™ package options) and high-voltage
power MOSFET in a single, low-profile CoolPAD (GROUND pin
connected) power package that is able to provide near unity
input power factor. The HiperPFS-2 devices eliminate the PFC
converter’s need for external current sense resistors, the power
loss associated with those components, and leverages an
innovative control technique that adjusts the switching frequency
over output load, input line voltage, and even input line cycle.
This control technique is designed to maximize efficiency over
the entire load range of the converter, particularly at light loads.
Additionally, this control technique significantly minimizes the EMI
filtering requirements due to its wide bandwidth spread spectrum
effect. The HiperPFS-2 also features an integrated non-linear
amplifier for enhanced load transient response, a user
programmable power good (PG) signal as well as user selectable
power limit functionality. HiperPFS-2 includes Power Integrations’
standard set of comprehensive protection features, such as
integrated soft-start, UV, OV, brown-in/out, and hysteretic
thermal shutdown. HiperPFS-2 also provides cycle-by-cycle
current limit for the power MOSFET, power limiting of the output
for overload protection, and pin-to-pin short-circuit protection.
HiperPFS-2’s innovative variable frequency continuous
conduction mode of operation (VF-CCM) minimizes switching
losses by maintaining a low average switching frequency, while
also varying the switching frequency in order to suppress EMI,
the traditional challenge with continuous conduction mode
solutions. Systems using HiperPFS-2 typically reduce the total X
and Y capacitance requirements of the converter, the inductance
of both the boost choke and EMI noise suppression chokes,
reducing overall system size and cost. Additionally, compared
with designs that use discrete MOSFETs and controllers,
HiperPFS-2 devices dramatically reduce component count and
board footprint while simplifying system design and enhancing
reliability. The innovative variable frequency, continuous
conduction mode controller enables the HiperPFS-2 to realize all
of the benefits of continuous conduction mode operation while
leveraging low-cost, small, simple EMI filters.
Many regions mandate high power factor for many electronic
products with high power requirements. These rules are
combined with numerous application-specific standards that
require high power supply efficiency across the entire load range,
from full load to as low as 10% load. High efficiency at light load
is a challenge for traditional PFC approaches in which fixed
MOSFET switching frequencies cause fixed switching losses on
each cycle, even at light loads. Besides featuring relatively flat
efficiency across the load range, HiperPFS-2 also enables higher
power factor at light loads. HiperPFS-2 simplifies compliance
with new and emerging energy-efficiency standards over a broad
market space in applications such as PCs, LCD TVs, notebooks,
appliances, pumps, motors, fans, printers, and LED lighting.
HiperPFS-2 advanced power packaging technology and high
efficiency simplifies the complexity of mounting the package and
thermal management, while providing very high power capabilities
in a single compact package; these devices are suitable for PFC
applications from 75 W to 425 W.
Product Highlights
Protected Power Factor Correction Solution
• Incorporates high-voltage power MOSFET, ultra-low reverse
recovery loss Qspeed diode, controller, and gate driver
• EN61000-3-2 Class D and Class C compliance
• Integrated protection features reduce external component count
• Accurate built-in brown-in/out protection
• Accurate built-in undervoltage (UV) protection
• Accurate built-in overvoltage (OV) protection
• Hysteretic thermal shutdown (OTP)
• Internal power limiting function for overload protection
• Cycle-by-cycle power switch current limit
• Internal non-linear amplifier for enhanced load transient
response
• No external current sense required
• Provides ‘lossless’ internal sensing via sense-FET
• Reduces component count and system losses
• Minimizes high current gate drive loop area
• Minimizes output overshoot and stresses during start-up
• Integrated power limit and frequency soft-start
• Improved dynamic response
• Input line feed-forward gain adjustment for constant loop
gain across entire input voltage range
• Eliminates up to 40 discrete components for higher reliability
and lower cost
Intelligent Solution for High Efficiency and Low EMI
• Continuous conduction mode PFC uses novel constant volt/
amp-second control engine
• High efficiency across load
• High power factor across load
• Low cost EMI filter
• Frequency sliding technique for light load efficiency improvements
• >95% efficiency from 10% load to full load at nominal input
voltages
• Variable switching frequency to simplify EMI filter design
• Varies over line input voltage to maximize efficiency and
minimize EMI filter requirements
• Varies with input line cycle voltage by >60 kHz to maximize
spread spectrum effect
Advanced Package for High Power Applications
• Up to 425 W peak output power capability in a highly
compact package
• Simple adhesive or clip mounting to heat sink
• No insulation pad required and can be directly connected to
heat sink
• Staggered pin arrangement for simple routing of board traces
and high-voltage creepage requirements
• Single package solution for PFC converter reduces assembly
costs and layout size
2
Rev. B 06/13
www.powerint.com
PFS7323-7329
Pin Functional Description
VOLTAGE MONITOR (V) Pin:
The VOLTAGE MONITOR pin is tied to the rectified high-voltage
DC rail through a large resistor (4 MΩ ±1%) to minimize power
dissipation and standby power consumption. Modifying this
resistor value affects peak power limit, brown-in/out thresholds
and will degrade input current quality (reduce power factor and
increase THD). A small ceramic capacitor (22 nF) is required
from the VOLTAGE MONITOR pin to SIGNAL GROUND pin to
bypass any switching noise present on the rectified DC bus.
This pin also features brown-in/out detection thresholds.
pin voltage has risen to ~95% of the set output voltage, the
POWER GOOD pin is pulled low. After start-up the output
voltage threshold at which the PG signal becomes highimpedance depends on the threshold programmed by the
POWER GOOD THRESHOLD pin resistor.
REFERENCE (R) Pin:
This pin is connected to an external precision resistor and is used for
an internal current reference source in the controller. The external
resistor is tied between the REFERENCE and SIGNAL GROUND
pins. The REFERENCE pin only has two valid resistor values to
select ‘Full’ (24.9 kΩ ±1%) and ‘Efficiency’ (49.9 kΩ ±1%) power
modes. A precision resistor with the values specified above must
be selected since this sets the internal current reference for the
controller. Other values beyond what is specified may adversely
effect the operation of the device. A bypass capacitor is also
recommended across the REFERENCE pin resistor to the SIGNAL
GROUND pin. For ‘Full’ power mode (24.9 kΩ) a capacitor
value of 470 pf and 1 nF for the ‘Efficiency’ mode with 49.9 kΩ.
SOURCE (S) Pin:
This pin is the source connection of the power switch.
BIAS POWER (VCC) Pin:
This is a 10.2-13 VDC bias supply used to power the IC. The
bias voltage must be externally clamped to prevent the BIAS
POWER pin from exceeding 15 VDC.
DRAIN (D) Pin:
This is the drain connection of the internal power switch.
BOOST DIODE CATHODE (K) Pin: (eSIP-16 package only)
This is the cathode connection of the internal Qspeed Diode.
H Package (eSIP-16D)
(Front View)
Pin 1 I.D.
3 4 5 6 7 8 9 1011 13 14 16
K
Exposed Metal (Both H and L
Packages) (On Package Edge)
Internally Connected to G Pin
G
Exposed Pad (Backside)
Internally Connected to
GROUND (G) Pin
G
H Package
(eSIP-16D)
(Back View)
V
R
G
C
FB
PG
PGT
VCC
S
S
1
D
NC
16 14 13 1110 9 8 7 6 5 4 3
K
FEEDBACK (FB) Pin:
This pin is connected to the main voltage regulation feedback
resistor divider network and is used for fast over and undervoltage protection. This pin also detects the presence of the
main voltage divider network at start-up.
L Package (eSIP-16G)
(Front View)
POWER GOOD THRESHOLD (PGT) Pin:
This pin is used to program the output voltage threshold where
the PG signal becomes ‘high-impedance’ representing the PFC
stage falling out of regulation. The low threshold for the PG
signal is programmed with a resistor between the POWER
GOOD THRESHOLD and SIGNAL GROUND pins.
Pin 1 I.D.
8 10
16
PG
11
14
NC
C
9
S
7
13
VCC
5
S
3
R
PGT
FB
G
Figure 2.
6
K
4
D
1
V
POWER GOOD (PG) Pin:
This pin is an open-drain connection that indicates that the
output voltage is in regulation. At start-up, once the FEEDBACK
NC
D
V
COMPENSATION (C) Pin:
This pin is used for loop compensation and voltage feedback.
The COMPENSATION pin is a high input-impedance reference
terminal that connects to the main voltage regulation feedback
resistor divider network. This pin also connects to the loop
compensation components comprising of a series RC network.
A 22 nF capacitor is also required between the COMPENSATION
and SIGNAL GROUND pins; this capacitor must be placed very
close to the device on the PCB to bypass any switching noise.
1
S
S
VCC
PGT
PG
FB
C
G
R
SIGNAL GROUND (G) Pin:
Discrete components used in the feedback circuit, including
loop compensation, decoupling capacitors for the supply (VCC)
and line-sense (V) must be referenced to the SIGNAL GROUND
pin. The SIGNAL GROUND pin is also connected to the tab of
the device. The SIGNAL GROUND pin must not be tied to
the SOURCE pin.
Exposed Pad
(Backside)
Not Shown
PI-6789-022213
Pin Configuration.
3
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Rev. B 06/13
PFS7323-7329
DRAIN (D)
BOOST DIODE CATHODE (K)
BIAS POWER (VCC)
VOLTAGE MONITOR (V)
IV
Input UV
(IUV+/IUV-)
+
INTERNAL
SUPPLY
INPUT
LINE INTERFACE
Peak
Detector
VCC+
-
SOFTSTART
IVPK MON
CUV/
FBOFF/
VREF
FBCOV
FBOV COFF IOCP VPG(H) IPGT FBCUV
MOFF (IREF - IV)
~(VO-VIN)
IREF
IV
CINT
IS
IOCP
+
LEB
Latch
Comparator
+
+
VOFF
VOFF
VCC
TIMER
SUPERVISOR
senseFET
Power
MOSFET
VE
Frequency
Slide
VE
+
IVPK
Transconductance
Error-Amplifier
Internal
1 kHz Filter
Reference
VREF
-
+
Comparator
-
mON is the switch
current sense scale
factor which is a function
of the peak input voltage
OCP
-
CINT
-
VCC
VOFF is a function of the error-voltage
(VE) and is used to reduce the
average operating frequency as a
function of output power
FBGM
-
FBCOV
FEEDBACK
(FB)
VFB
Buffer and
De-Glitch Filter
+
-
+
FBGM
FBON/
FBOFF
+
Feedback-OVP/OFF
Comparator
FEEDBACK/
COMPENSATION Pin
OV/UV
REFERENCE
(R)
REFERENCE
AND BAND GAP
-
+
-
FBCUV
COMPENSATION
(C)
C-UV/OFF
Comparator
PON × MON × IS
CUV/COFF
+
INPUT UV
OTP SOA
VFB
+
VCC
VPG(H)
IPGT
POWER GOOD
THRESHOLD
(PGT)
POWER GOOD
(PG)
SOURCE (S)
Figure 3.
GROUND (G)
PI-6697-050312
Functional Block Diagram.
Functional Description
The HiperPFS-2 is a variable switching frequency boost PFC
solution. More specifically, it employs a constant amp-second
on-time and constant volt-second off-time control algorithm.
This algorithm is used to regulate the output voltage and shape
the input current to comply with regulatory harmonic current
limits (high power factor). Integrating the switch current and
controlling it to have a constant amp-sec product over the
on-time of the switch allows the average input current to follow
the input voltage. Integrating the difference between the output
and input voltage maintains a constant volt-second balance
dictated by the electro-magnetic properties of the boost
inductor and thus regulates the output voltage and power.
More specifically, the control technique sets constant voltseconds for the off-time (tOFF). The off-time is controlled such
that:
^ VO - V IN h # t OFF = K 1 (1)
Since the volt-seconds during the on-time must equal the
volt-seconds during the off-time, to maintain flux equilibrium in
the PFC choke, the on-time (tON) is controlled such that:
V IN # t ON = K 1 (2)
The controller also sets a constant value of charge during each
on-cycle of the power MOSFET. The charge per cycle is varied
gradually over many switching cycles in response to load
changes so it can be regarded as substantially constant for a
half line cycle. With this constant charge (or amp-second)
control, the following relationship is therefore also true:
I IN # t ON = K 2 (3)
Substituting tON from (2) into (3) gives:
I IN = V IN # K 2 K1
(4)
4
Rev. B 06/13
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PFS7323-7329
VOFF
(VOUT-VIN)dt
Latch
SET
Gate
Drive (Q)
Maximum
ON-time
Minimum
OFF-time
1.2
1
0.8
0.6
0.4
0.2
0
0
Idealized Converter Waveforms.
Control Engine
The controller features a low bandwidth error-amplifier which
connects its non-inverting terminal to an internal voltage
reference of 6 V. The inverting terminal of the error-amplifier is
available on the external CONTROL pin which connects to the
loop compensation and voltage divider network to regulate the
output voltage. The FEEDBACK pin connects directly to the
divider network for fast transient load response.
The internal sense-FET switch current is integrated and scaled
by the input voltage peak detector current sense gain (MON) and
compared with the error-amplifier signal (VE) to determine the
cycle on-time. Internally the difference between the input and
output voltage is derived and the resultant is scaled, integrated,
and compared to a voltage reference (VOFF) to determine the
cycle off-time. Careful selection of the internal scaling factors
produce input current waveforms with very low distortion and
high power factor.
Line Feed-Forward Scaling Factor (MON)
The VOLTAGE MONITOR (V) pin current is used internally to
derive the peak of the input line voltage which is used to scale
the gain of the current sense signal through the MON variable.
This contribution is required to reduce the dynamic range of the
control feedback signal as well as maintain a constant loop gain
over the operating input line range. This line-sense feedforward gain adjustment is proportional to the square of the
peak rectified AC line voltage and is adjusted as a function of
VOLTAGE MONITOR pin current. The line-sense feed-forward
gain is also important in providing a switch power limit over the
input line range. Besides modifying brown- in/out thresholds,
0.2
0.4
0.6
0.8
1
1.2
1.4
Normalized to Peak Power Rating
Figure 5.
Typical Normalized Output Voltage Characteristics as Function of Normalized Peak Load Rating
Below the brown-in threshold (IUV+) the power limit is reduced
when the device is operated in the ‘Full’ power mode as shown
in the figure below.
Normalized Minimum Power Limit
Figure 4.
Timing
Supervisor
Beyond the specified peak power rating of the device, the
internal power limit feature will regulate the output voltage below
the set regulation threshold as a function of output overload
beyond the peak power rating. Figure 5 illustrates the typical
regulation characteristic as function of load.
PI-6216-113010
IS dt
Latch
RESET
This characteristic is optimized to maintain a relatively constant
internal error-voltage level at full load from an input line of 100 to
230 VAC input.
1.2
PI-6940-013013
VE
PI-5335-111610
This control produces a continuous mode power switch current
waveform that varies both in frequency and peak current value
across a line half-cycle to produce an input current proportional
to the input voltage.
the VOLTAGE MONITOR pin resistor also affects power limit of
the device.
Normalized to Set Output Voltage
Regulation Threshold
The relationship of (4) demonstrates that by controlling a
constant amp-second on-time and constant volt-second
off-time, the input current IIN is proportional to the input voltage
VIN, therefore providing the fundamental requirement of power
factor correction.
1
0.8
0.6
0.4
0.2
0
70
75
80
85
90
95
100
Input Voltage (VAC)
Figure 6.
Normalized Minimum Power Limit as Function of Input Voltage.
As the input line voltage is reduced toward the brown-out
threshold (IUV-) and if the load exceeds the power limit derating
the boost output voltage will drop out of regulation in
accordance to Figure 6.
5
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Rev. B 06/13
PFS7323-7329
Internal Error-Voltage (VE)
VCC
Voltage
The minimum rated peak power shown in Table 1 is not derated
below the brown-in threshold when the device is operated in
the ‘Efficiency’ mode.
VCC+
To reduce switch and output diode current stress at start-up,
the HiperPFS slews the internal error-voltage from zero to its
steady-state value at start-up. Figure 7 illustrates the relative
relationship between the application of VCC and power limit
soft-start function through the internal error-voltage. The
error-voltage has a controlled slew rate of 0.25 V/ms at start-up,
corresponding to the tSOFT time duration for a full scale error
voltage of 5 V.
tSTART-DELAY
tSOFT
~5 V
The beginning of soft-start is gated by the VCC+, REFERENCE,
CONTROL and FEEDBACK pin voltage thresholds in the
sequence described below. Once the applied VCC is above the
VCC+ threshold, conditions for REFERENCE, COMPENSATION
t
PI-5336-110810
Figure 7.
Soft-Start with Pin-to-Pin Short-Circuit Protection
The FEEDBACK pin which is connected to a resistor voltage
divider provides a means to overcome the inherently slow
feedback loop response. The controller has an integrated
non-linear amplifier function to limit the maximum overshoot
and undershoot during load transient events.
Power Limit Soft-Start Function.
Soft-Start
Check
Sequence
Is
VCC > VCC+?
NO
Is
IR Within
Bounds for
Efficiency or
Full Mode?
Is
IV > IUV+?
NO
YES
YES
YES
Apply 0.5 µA on
on FB Pin to
Check Open
FB Pin
Apply
6 mA V Pin
Current Sink
YES
YES
Apply PGT
Current Source
Is OTP OK?
Set Internal
Power Limit
YES
NO
Is
VV < 1 V?
Is PG ‘OFF’
(PG High
Impedance)?
NO
YES
NO
Is
IV > IUV+
YES
NO
YES
Is
IR Within
Bounds for
Efficiency or
Full Mode?
Increase
FB Pin Current
to 20 µA
YES
Source ~3 mA
to C Pin
YES
NO
YES
Is
VFB > FBOFF
VFB < FBOV?
NO
NO
YES
Detect Input
Voltage Peak
YES
Is VC > COFF?
Is the NLA
Charging or
Discharging?
YES
NO
Feedback
short to C Pin
NO
YES
Is
VFB > FBOFF
VFB < FBON
VC > COFF
OTP OK?
NO
Start
Converter
YES
Is VC > 3 V?
NO
YES
Is the NLA
Charging or
Discharging?
YES
NO
Decrease
FB Pin Current
to 0.5 µA
YES
YES
Remove
6 mA V Pin
Current Sink
Slow Power
Limit Over
Soft-Start
Duration
YES
PI-6698-013013
Figure 8.
Start-Up Sequence.
6
Rev. B 06/13
www.powerint.com
230 VAC
135 VAC
90 VAC
90
180 VAC
80
115 VAC
70
60
50
40
30
VIN = 115 VAC
Expected Frequency
Range at Peak
Rated Load
75% Peak Load
90
80
70
50% Peak Load
60
50
25% Peak Load
40
30
20
20
Peak Load
10
10
45
0
90
135
180
45
0
Line Conduction Angle (°)
Figure 9.
100% Peak Load
100
Frequency (kHz)
Frequency (kHz)
100
120
110
PI-6695-013013
120
110
PI-6694-013013
PFS7323-7329
90
135
180
Line Conduction Angle (°)
(a) Frequency Variation Over Line Half-Cycle as a Function of Input Voltage (b) Frequency Variation Over Line Half-Cycle as a Function of Load.
~5 V
~1.25 V
VOFF(MAX)
VOFF
~5 V
VIN < ~140 VAC
~1.25 V
VIN > ~170 VAC
~0.8 V
VE
~5 V
(Full Power)
~140 VAC
VIN
~170 VAC
PI-6864-050313
Figure 10. VOFF vs. VE and VOFF vs. Input Voltage.
and FEEDBACK pins are satisfied and the sensed VOLTAGE
MONITOR pin current is above IUV+ ,the IC applies a ~6 mA
current sink through the VOLTAGE MONITOR pin and checks
that the status of the REFERENCE pin voltage is still in a valid
range. This checks to ensure that the FEEDBACK and
REFERENCE pins are not shorted together. In the event that
these pin voltage are shorted or the REFERENCE pin current is
no longer in the valid range, VOLTAGE MONITOR pin holds the
6 mA current sink indefinitely until the REFERENCE pin is in the
valid range. Figure 8 illustrates this sequence.
Timing Supervisor and Operating Frequency Range
Since the controller is expected to operate with a variable
switching frequency over the line frequency half-cycle, typically
spanning a range of 24 – 110 kHz, the controller also features a
timing supervisor function which monitors and limits the
maximum switch on-time and off-time as well as ensures a
minimum cycle off-time.
Figure 9a shows the typical half-line frequency profile of the
device switching frequency as a function of input voltage at
peak load conditions. Figure 9b shows for a given line
condition the effect of EcoSmart™ to the switching frequency
as a function of load. The switching frequency is not a function
of boost choke inductance in CCM (continuous conduction
mode) operation.
EcoSmart
The HiperPFS-2 includes an EcoSmart mode wherein the
internal error signal (VE) is used to detect the converter output
power. Since the internal error-signal is proportional to the
output power, this signal level is used to set the average
switching frequency as a function of output power. The off-time
integrator control reference (VOFF) is controlled with respect to
the internal error-voltage level (output power) to allow the
converter to maintain output voltage regulation and relatively flat
conversion efficiency between 20% to 100% of rated load
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Rev. B 06/13
PFS7323-7329
which is essential to meet many efficiency directives. The
degree of frequency slide is also controlled as a function of
peak input line voltage, at high input line the maximum off-time
voltage reference at zero error-voltage will be approximately 1/4
of the maximum value at low input line conditions.
The lower VOFF slope reduces the average frequency swing for
high input line operation.
Burst-Mode for No-Load Power Consumption Reduction
Unlike the original HiperPFS which had the ability to reduce the
minimum on-time to zero, the minimum on-time in HiperPFS-2
has a minimum value of 500 ns to enable burst-mode operation
at no-load.
Since the minimum on-time is 500 ns, at no-load the output
voltage will climb until the device shuts off due to the voltage on
the COMPENSATION pin reaching the COV threshold. The
output voltage ripple at no-load to light load will be increased as
a result of the burst-mode operation.
A higher minimum on-time and inclusion of the COV comparator
are the main elements in the design to enable this burst-mode
operation at no-load. The burst-mode was added to reduce the
power stage no-load consumption to below 0.5 W when the
boost converter is designed with a ferrite boost choke.
Power Good Signal (PG)
The HiperPFS-2 features a ‘power good’ (PG) circuit which
comprises of an internal comparator that at start-up turns ‘on’ a
switch when the sensed output voltage on the FEEDBACK pin
rises to ~95% (VPG(H) threshold) of the set output voltage threshold.
During start-up prior to the output voltage reaching VPG(H) the PG
signal is in a high-impedance state (internal switch is in ‘off’ state).
When the AC input voltage is removed or other fault occurs
after start-up, the power good signal transitions from ‘on’ to ‘off’
state once the sensed output voltage on the FEEDBACK pin
falls to a user selected threshold programmed with a resistor on
the POWER GOOD THRESHOLD pin. The POWER GOOD
THRESHOLD pin has a fixed source current of IPGT and this
combined with the power good threshold resistor sets the
threshold when the power good signal transitions from the ‘on’
state to the high-impedance high-state as the PFC output
voltage falls out of regulation.
The POWER GOOD THRESHOLD pin has an internal 100 ms
de-glitch filter (tPG ) to prevent noise events from falsely setting
the VPG(L) threshold.
In the event a load fault prevents the boost from achieving
regulation (~95% of the set output voltage threshold) the PG
function will remain in the high-impedance state and will not
annunciate when a output voltage has fallen below the user
programmed VPG(L) threshold.
The VPG(L) user programmed threshold is enabled once VPG(H)
threshold has been reached.
If the PGT programming resistor is left open, the power good
function is disabled and remains in the high-impedance (‘off’)
state, whereas if the POWER GOOD THRESHOLD pin is
shorted to the GROUND pin the power good signal will remain
in the low (‘on’) state until the PFC output voltage has fallen to
the CUV threshold.
Similar to the condition described above, if the value of the PGT
resistor is such that the VPG(L) threshold is greater than the VPG(H)
threshold the PG signal will remain in the high-impedance offstate.
Power good function is not valid under the following conditions:
A. VCC is not in a valid range. Below VCC-, the power good
function is not valid.
B. REFERENCE pin resistor is in an invalid range. If the
REFERENCE pin resistor is not either 24. 9 kW for ‘Full’ or
49.9 kW for ‘Efficiency’ mode, the power good signal is not
valid. Power good will go to high-impedance state (internal
MOSFET is ‘off’) at the end of the fast soft-shutdown initiated
by the REFERENCE pin resistor fault.
C. The valid programming range of PGT is between 275 V to
360 V. Programming an output voltage below 275 VDC to
trigger PG is invalid.
100% VOUT (380 V)
95% VOUT (361 V)
Output Voltage
Rising
87.5% VOUT (333 V)
Set internally
by VPG(H)
Set externally
by RPG
R PG = 0.875 # V REF = 5.25 V = 105 kX
I PG
50 nA
tPG
tPG
PG = High Impedance
PG = On-State
Output Voltage
Falling
PG = High Impedance
PI-6700-040512
Figure 11. Power Good Function Description.
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PFS7323-7329
Normal Range for
‘Full Mode’
R = 24.9 kΩ
IV < ~48 µA
IOCP
Normal Range for
‘Efficiency Mode’
R = 49.9 kΩ
IC-OFF
IC-OFF
IC-OFF
25 μA
20 μA
30 μA
IV > ~59 µA
50 μA
40 μA
60 μA
PI-6701-030212
VIN
~140 VAC
PI-6863-050313
Figure 12. REFERENCE Pin Current Operating Range.
D. Once the start-up sequence check has passed and the
converter goes into soft-start and if PGT is shorted to
SIGNAL GROUND pin, then the PG signal will toggle to the
low state (internal MOSFET is ‘on’) when the output voltage
reaches 85-100% of the set regulation threshold and will
remain in this state until the output voltage reaches zero volt
or conditions in A, B or C occur.
E. Once the start-up sequence check has passed and the
converter goes into soft-start and if PGT is open, then the
PG signal will remain in the high-impedance state (internal
MOSFET is ‘off’).
Reference and Selectable Power Limit
Besides the internal current reference source, the precision
resistor on the REFERENCE pin also allows user selection
between ‘full’ and ‘efficiency’ power limit for each device. The
efficiency power mode will permit user selection of a larger
device for a given output power requirement for increased
conversion efficiency.
In ‘full’ power mode the REFERENCE pin resistor is 24.9 kΩ
±1% and the ‘Efficiency’ power limit mode is selected with a
49.9 kΩ ±1% resistor.
If the REFERENCE pin is shorted (to GROUND pin) or open
circuited the IC will initiate a fast soft-shutdown and disable the
power MOSFET and remain disabled until all the conditions for
the start-up sequence are satisfied.
The REFERENCE pin resistor value and power mode is latched
at start-up.
Protection Modes
VOLTAGE MONITOR (V) Pin Shutdown
The VOLTAGE MONITOR pin features a shutdown protection
mode which can be used with the VOLTAGE MONITOR pin
resistor or external circuitry to cover system faults. During
start-up (1 V < VFB < 5.8 V) in the event the current through the
VOLTAGE MONITOR pin exceeds the IV(OFF) threshold for a
duration exceeding approximately (1 μs), the IC disables the
internal MOSFET for the entire duration that the VOLTAGE
MONITOR pin current is above IV(OFF). In normal operation, if the
current through the VOLTAGE MONITOR pin exceeds the IV(OFF)
threshold for a duration exceeding tV(OFF), the IC will re-initiate the
start-up sequence.
~170 VAC
Figure 13. Line Dependent OCP.
Brown-In Protection (IUV+)
The VOLTAGE MONITOR pin features an input line undervoltage
detection to limit the minimum start-up voltage detected
through the VOLTAGE MONITOR pin. This detection threshold
will inhibit the device from starting at very low input AC voltage.
Brown-Out Protection (IUV-)
The VOLTAGE MONITOR pin features a brown-out protection
mode wherein the HiperPFS will turn-off when the VOLTAGE
MONITOR pin current is below the Line UV- threshold (IUV-) for a
period exceeding the tBROWN-OUT time period. In the event a
single half-line cycle is missing (normal operating line frequency
is 47 to 63 Hz) the brown-out protection will not be activated.
The HiperPFS-2 soft-shutdown in effect gradually reduces the
internal error-voltage to zero volts at rate of 1 V/ms to decay the
power MOSFET on-time to zero.
At peak power (VE ~5 V) the shutdown time will be approximately
5 ms. The internal error-voltage is held at 0 V for as long as the
input peak voltage is below the brown-in (IUV+) threshold. The
internal error-voltage controlled slew to 0 V gradually reduces
the switch on-time to zero to deplete energy stored in the boost
choke as well as input EMI filter for power-down. Once the
error-voltage reaches zero volts the controller is effectively in an
off-state (gated by 5 ms timer) and will restart once all the
conditions of soft-start are satisfied.
At start-up and during soft-start the brown-out threshold (same
as Line UV-) is reduced to IUV(SS) and brown-out timer is also
extended to tUV(SS) (soft-start brown-out timer).
Soft-start brown-out threshold (IUV(SS)) is reset to IUV- once the
internal error-voltage has begun to fall (indicating the converter
has reached steady-state output voltage regulation).
The soft-start brown-out timer is reset to the normal brown-out
timer once the internal error-voltage has begun to fall (indicating
the converter has reached steady-state output voltage regulation)
and the VOLTAGE MONITOR pin current exceeds IUV-.
If the VOLTAGE MONITOR pin current is still below the IUV(SS)
threshold after the end of the soft-start brown-out timer (tUV(SS)),
then the converter will fail to start and initiate a soft-shutdown
followed by a soft start-up sequence as described in flowchart
in Figure 8.
9
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Rev. B 06/13
PFS7323-7329
Temporarily reducing the brown-out threshold prevents false
turn-off at high power start-up when voltage drop across the
input bridge rectifier and filter stage may cause the rectified
input to sag below the brown-out threshold.
Increasing the brown-out timer during soft-start permits a longer
time for an in-line AC-side NTC to reduce its resistance and
increase the voltage presented to the VOLTAGE MONITOR pin.
In the event the converter does not reach regulation at start-up
(overload or power limit condition) CUV protection threshold is
not activated and both the IUV(SS) and tUV(SS) are not reset.
It is expected that while the input voltage peak is below the
brown-out threshold (IUV-) during a line cycle drop out or line sag
event the internal peak detector will force refresh the line
feed-forward gain (mON) to the minimum value at the tREFRESH
sample rate.
Similar to the original HiperPFS, the controller latches the OCP
threshold in the event of an AC line cycle drop-out when the
peak sense is for a high input line condition (VIN > 170 VAC).
Fast Output Voltage Overvoltage Protection (FBOV )
This family features a FEEDBACK pin that is connected directly
to the output voltage resistor divider network to permit fast
feedback information to the controller for fast load transient
response.
The COMPENSATION pin which is also connected to the
voltage divider network includes a resistor to isolate the slow
feedback path and loop compensation network into the
controller for steady-state output voltage regulation.
Comparators on the FEEBACK and COMPENSATION pins are
used to verify that the pins are not open-circuited and that the
main voltage divider voltage at start-up is greater than FBOFF
and COFF in order to complete the start-up fault detect sequence.
After start-up the FBOFF and COFF thresholds remain enabled.
Similarly to the original HiperPFS, this controller includes internal
FBOV (FEEDBACK pin overvoltage), COV (COMPENSATION pin
overvoltage) and CUV (COMPENSATION pin undervoltage)
protection thresholds that are detected through the FEEDBACK
and COMPENSATION pins. Deglitch filters (tFB(OV) and tC(UV)) are
also used to prevent the controller from falsely triggering this
protection mode.
A FBOV event in excess of the tFB(OV) delay will terminate the
switch cycle immediately.
The COMPENSATION pin also features an output voltage
undervoltage detection threshold to detect an overload or
open-loop condition (broken feedback). In the event the falling
edge of the voltage on the COMPENSATION pin falls below the
CUV threshold, the MOSFET is disabled and the soft-start
start-up sequence is initiated.
The COMPENSATION pin undervoltage protection (CUV ) mode is
disabled during start-up and enabled once the COMPENSATION
pin voltage exceeds approximately 5.8 V. The brown-out
threshold is also reset from IUV(SS) to IUV- under the same conditions
as activation of the CUV threshold.
VCC Undervoltage Protection (UVLO)
The BIAS POWER (VCC) pin has an undervoltage lock-out
protection which inhibits the IC from starting unless the applied
VCC voltage is above the VCC+ threshold. The IC initiates a
soft-start once the VCC pin voltage exceeds the VCC+ threshold.
After start-up the IC will continue to operate until the VCC pin
voltage has fallen below VCC- level. The absolute maximum
voltage of the VCC pin is 15 V which must be externally limited
to prevent damage to the IC.
Over-Current Protection
The device includes a cycle-by-cycle over-current-protection
(OCP) mode which protects the device in the event of a
catastrophic fault. The OCP mode in the HiperPFS-2 is input
line dependent as shown in Figure 13. The intention of OCP in
this device is strictly protection of the internal power MOSFET
and is not intended to protect the converter from output
short-circuit or overload fault conditions.
The HiperPFS-2 latches the high input line OCP for a 1/2 line
cycle and updates the OCP status after the expiration of a 5 ms
block-out timer. This feature has particular benefit for hard-start
after an AC line cycle drop where the peak detector may falsely
detect a low input line condition even though the input is at high
input line.
A leading edge blanking circuit inhibits the current limit
comparator for a short time (tLEB) after the power MOSFET is
turned on. This leading edge blanking time is set so that
current spikes caused by capacitance and rectifier reverse
recovery time will not cause premature termination of the
MOSFET conduction.
Safe Operating Area (SOA) Mode
Since the cycle-by-cycle OCP mechanism described above
does not prevent the possibility of inductor current ‘stair-casing’,
an SOA mode is also featured. Rapid buildup of the device
current can occur in the event of inductor saturation or when
the input and output voltages are equal (no or very short
inductor reset time).
The SOA mode is triggered whenever the device reaches
current limit (IOCP) and the on-time is less than tSOA.
The SOA mode forces an off-time equal to tOCP and pulls the
internal error-voltage (VE) down to approximately 1/2 of its set
value.
Open FEEDBACK Pin Protection
The FEEDBACK pin also features a static current of IFB that is
continuously sourced out of the pin to protect against a fault
related to an open FEEDBACK pin. The internal current source
introduces a static offset to the output regulation which must be
accounted for in selecting the output feedback regulation
components.
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PFS7323-7329
Hysteretic Thermal Shutdown
The thermal shutdown circuitry senses the controller die
temperature. The threshold is set at 117 °C typical with a 49 °C
hysteresis. When the die temperature rises above this threshold
(OTP) (117 °C +8/-7 °C), the controller initiates a fast softshutdown and remains disabled until the die temperature falls
by ~49°C, at which point the device will re-initiate the soft-start
sequence.
In the event an OTP is detected when the VOLTAGE MONITOR
pin current is below IUV+ threshold, the device will initiate a
soft-shutdown and remain disabled until all the conditions for
the start-up (soft-start sequence) are satisfied. In this mode of
operation the OTP hysteresis is disabled.
When soft-shutdown is initiated by an over-temperature fault
(OTP) the brown-out timer delay (tBROWN-OUT ) is disabled. The
behavior of OTP depends on the input voltage peak detected
following the thermal fault. If the input peak voltage detected
after the thermal fault is below IUV+, OTP hysteresis is disabled,
however if the peak input voltage after the thermal fault is above
IUV+ then the OTP hysteresis is enabled prior to re-initiating the
soft-start sequence.
The maximum time delay for soft-shutdown to occur after an
OTP event is detected is tREFRESH.
In the event the input voltage is reduced below the brown-in
threshold and an OTP event occurs (no OTP hysteresis) and the
input voltage is raised immediately above brown-in before the
controller junction temperature falls below the OTP threshold,
the controller will initiate a soft-start once the controller junction
is just below the OTP threshold. Depending on the system
thermal conditions, the controller could initiate OTP shutdown
again because of insufficient time to cool down the controller.
The OTP shutdown that occurs when the input voltage is above
brown-in will have hysteresis enabled.
Output Power Table
eSIP Package
Efficiency Power Mode R = 49.9 kW
Product
PFS7323L
Maximum Continuous
Output Power Rating at
90 VAC2
Minimum3
Maximum
60 W
80 W
Peak Output Power
Rating at 90 VAC4
Full Power Mode R = 24.9 kW
Maximum Continuous
Output Power Rating at
90 VAC2
Minimum3
Maximum
90 W
85 W
110 W
Peak Output Power
Rating at 90 VAC4
120 W
PFS7324L
80 W
110 W
120 W
100 W
130 W
150 W
PFS7325L
110 W
150 W
165 W
140 W
185 W
205 W
PFS7326H
140 W
185 W
205 W
180 W
230 W
260 W
PFS7327H
175 W
230 W
255 W
220 W
290 W
320 W
PFS7328H
210 W
280 W
310 W
270 W
350 W
385 W
PFS7329H
235 W
320 W
345 W
293 W
380 W
425 W
Table 2. Output Power Table.
Notes:
1. See Key Application considerations.
2. Maximum practical continuous power at 90 VAC in an open-frame design with adequate heat sinking, measured at 50 °C ambient.
3. Recommended lower range of maximum continuous power for best light load efficiency; HiperPFS-2 will operate and perform below this level.
4. Internal output power limit.
11
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Rev. B 06/13
PFS7323-7329
Application Example
A High Efficiency, 350 W, 385 VDC Universal Input PFC
The circuit shown in Figure 14 is designed using a PFS7328H
device from the HiperPFS-2 family of integrated PFC controllers.
This design is rated for a continuous output power of 350 W
and provides a regulated output voltage of 385 VDC nominal
maintaining a high input power factor and overall efficiency from
light load to full load.
The PFS7328H IC requires a regulated supply of 12 V for
operation and must not exceed 15 V. Resistors R10, R11, R12,
Zener diode VR1, and transistor Q2 form a series pass regulator
that prevents the supply voltage to IC U1 from exceeding 12 V.
Capacitors C6, and C9 filter the supply voltage and provide
decoupling to ensure reliable operation of IC U1. Diode D5
provides reverse polarity protection.
Fuse F1 provides protection to the circuit and isolates it from the
AC supply in case of a fault. Diode bridge BR1 rectifies the AC
input. Capacitors C1, C2, C3, and C4 together with inductors
L1, L2, and L3 form the EMI filter reducing the common mode
and differential mode noise. Resistors R1, R2 and CAPZero, IC
U2 are required to discharge the EMI filter capacitors once the
circuit is disconnected. CAPZero eliminates static losses in R1
and R2 by only connecting these components across the input
when AC is removed.
Resistor R15 programs the output voltage level [via the POWER
GOOD THRESHOLD (PGT) pin] below which the POWER
GOOD [PG] pin will go into a high-impedance state. IC U1 is
configured in full power mode by resistor R14. Capacitor C8
decouples REFERENCE pin of IC U1.
The boost converter stage consists of inductor L5, and the
HiperPFS-2 IC U1. This converter stage works as a boost
converter and controls the input current of the power supply
while simultaneously regulating the output DC voltage. Diode
D3 prevents a resonant build up of output voltage at start-up by
bypassing inductor L5 while simultaneously charging output
capacitor C13. Thermistor RT1 limits the inrush input current of
the circuit at start-up and prevents saturation of L5. In most
high-performance designs, a relay will be used to bypass the
thermistor after start-up to improve power supply efficiency.
Capacitor C10 is used for reducing the loop length and area of
the output circuit to reduce EMI and overshoot of voltage
across the drain and source of the MOSFET inside U1 at each
switching instant.
Divider network comprising of resistors R18, R19, R20, and
R21 are used to scale the output voltage and provide feedback
to IC U1. Capacitor C14 enables rapid correction of output
voltage overshoot or undershoot resulting from transient loading.
The rectified AC input voltage of the power supply is sensed by
IC U1 using resistors R7, R8 and R9. The capacitor C7 filters
any noise on this signal.
Resistor R17, R16, and capacitors C12 and C11 are required for
shaping the loop response of the feedback network. The
combination of resistor R16 and capacitor C12 provide a low
frequency zero and the resistor R17, R16 and capacitor C12
form a low frequency pole. C15 and R22 attenuate highfrequency noise.
Diode D6 protects against an accidentally shorted capacitor
C12 by safely shutting down the IC.
D3
1N5408-T
D
BR1
GBU8K-BP
800 V
F1
6.3 A
L
R1
220 kΩ
C1
680 nF
275 VAC
D1
CAPZero
U2
CAP005DG
C2
220 nF
275 V
RV1
320 VAC
E
C5
1 µF
450 V
R3
10 Ω
2W
1%
D2
R2
220 kΩ
C4
680 pF
250 VAC
RT1
2.5 Ω
N
t
C14
47 nF
200 V
R20
1.6 MΩ
1%
VCC
CONTROL
FB
C
HiperPFS-2
U1
PFS7328H
R17
487 Ω
PGT
S
O
V
G
R
L3
220 µH
R16
7.5 kΩ
1%
L1
Ferrite Bead
R5
16 kΩ
R4
10 kΩ
R10
1Ω
1%
Q1
MMBT4403
D4
BAV16
DC
OUT
D6
BAV116
R12
2.2 kΩ
1%
3
Auxiliary
Power
Supply
1
+
Remote
ON
C13
270 µF
450 V
C10
10 nF
1 kV
Q2
MMBT4401LT1G
+
R6
3 kΩ
R19
787 kΩ
PG
R8
1.5 MΩ
1%
R9
1 MΩ
1%
+
R18
1.5 MΩ
1%
R7
1.5 MΩ
1%
C3
680 pF
250 VAC
L2
9 mH
VO
K
L5
360 µH
U3
LTV817A
D1
S1AB
D5
S1AB
4
D2
C6
47 µF
50 V
R15
100 kΩ
1%
VR1
1N4743A
13 V
2
R11
1Ω
1%
C7
22 nF
50 V
R14
24.9 kΩ
1%
C8
470 pF
50 V
C9
3.3 µF
25 V
C11
22 nF
25 V
C12
2.2 µF
25 V
R22
3 kΩ
C15
47 nF
25 V
R21
60.4 kΩ
1%
VO
PI-6971-041713
Figure 14. 350 W PFC using PFS7328H.
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PFS7323-7329
Design, Assembly, and Layout Considerations
Power Table
The data sheet power table as shown in Table 2 represents the
maximum practical continuous output power based on the
following conditions:
For the universal input devices (PFS7323L-PFS7329H):
1. An input voltage range of 90 VAC to 264 VAC.
2. Overall efficiency of at least 93% at the lowest operating
voltage.
3. 385 V nominal output.
4. Sufficient heat sinking to keep device temperature ≤100 ºC.
Operation beyond the limits stated above will require derating.
Use of a nominal output voltage higher than 390 V is not
recommended for HiperPFS-2 based designs. Operation at
voltages higher than 390 V can result in higher than expected
drain-source voltage during line and load transients.
HiperPFS-2 Selection
Selection of the optimum HiperPFS-2 part depends on required
maximum output power, PFC efficiency and overall system
efficiency (when used with a second stage DC-DC converter),
heat sinking constraints, system requirements and cost goals.
The HiperPFS-2 part used in a design can be easily replaced
with the next higher or lower part in the power table to optimize
performance, improve efficiency or for applications where there
are thermal design constraints. Minor adjustments to the
inductance value and EMI filter components may be necessary
in some designs when the next higher or the next lower
HiperPFS-2 part is used in an existing design for performance
optimization.
Every HiperPFS-2 family part has an optimal load level where it
offers the most value. Operating frequency of a part will
change depending on load level. Change of frequency will
result in change in peak-to-peak current ripple in the inductance
used. Change in current ripple will affect input PF and total
harmonic distortion of input current.
Input Fuse and Protection Circuit
The input fuse should be rated for a continuous current above
the input current at which the PFC turns-off due to input under
voltage. This voltage is referred to as the brown-out voltage.
The fuse should also have sufficient I2t rating in order to avoid
nuisance failures during start-up. At start a large current is
drawn from the input as the output capacitor charges to the
peak of the applied voltage. The charging current is only limited
by any inrush limiting thermistors, impedance of the EMI filter
inductors, ESR of output capacitor and the forward resistance of
the input rectifier diodes.
A MOV will typically be required to protect the PFC from line
surges. Selection of the MOV rating will depend on the energy
level (EN1000-4-5 Class level) to which the PFC is required to
withstand.
A suitable NTC thermistor should be used on the input side to
provide inrush current limiting. Choice of this thermistor should
be made depending on the inrush current specification for the
power supply. NTC thermistors may not be placed in any other
location in the circuit as they fail to limit the stress on the part in
the event of line transients and also fail to limit the inrush current
in a predictable manner. Example shown in Figure 14 shows
the circuit configuration that has the inrush limiting NTC thermistor
on the input side which is bypassed with a relay after PFC
start-up. This arrangement ensures that a consistent inrush
limiting performance is achieved by the circuit.
Input EMI Filter
The variable switching frequency of the HiperPFS-2 effectively
modulates the switching frequency and reduces conducted EMI
peaks associated with the harmonics of the fundamental
switching frequency. This is particularly beneficial for the
average detection mode used in EMI measurements.
The PFC is a switching converter and will need an EMI filter at
the input in order to meet the requirements of most safety
agency standards for conducted and radiated EMI. Typically a
common mode filter with X capacitors connected across the
line will provide the required attenuation of high frequency
components of input current to an acceptable level. The
leakage reactance of the common mode filter inductor and the
X capacitors form a low pass filter. In some designs, additional
differential filter inductors may have to be used to supplement
the differential inductance of the common mode choke.
A filter capacitor with low ESR and high ripple current capability
should be connected at the output of the input bridge rectifier.
This capacitor reduces the generation of the switching frequency
components of the input current ripple and simplifies EMI filter
design. Typically, 0.33 mF per 100 W should be used for
universal input designs and 0.15 mF per 100 W of output power
should be used for 230 VAC only designs.
It is often possible to use a higher value of capacitance after the
bridge rectifier and reduce the X capacitance in the EMI filter.
Regulatory requirements require use of a discharge resistor to
be connected across the input (X) capacitance on the AC side
of the bridge rectifier. This is to ensure that residual charge is
dissipated after the input voltage is removed when the
capacitance is higher than 0.1 mF. Use of CAPZero integrated
circuits from Power Integrations, helps eliminate the steadystate losses associated with the use of discharge resistors
connected permanently across the X capacitors.
Inductor Design
It is recommended that the inductor be designed with the
maximum operating flux density less than 0.3 T and a peak flux
density less than 0.39 T at maximum current limit when a ferrite
core is used. If a core made from Sendust or MPP is used, the
flux density should not exceed 1 T. A powder core inductor will
have a significant drop in inductance when the flux density
approaches 1 T.
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PFS7323-7329
For high performance designs, use of Litz wire is recommended
to reduce copper loss due to skin effect and proximity effect.
For toroidal inductors the numbers of layers should be less than
3 and for bobbin wound inductors, inter layer insulation should
be used to minimize inter layer capacitance. For ferrite core
inductor, a nominal KP value of 0.35 is recommended for an
optimal design. For Sendust core inductor, a nominal KP value
of 0.6 is recommended for an optimal design.
Output Capacitor
For a 385 V nominal PFC, use of a electrolytic capacitor with
450 V or higher continuous rating is recommended. The
capacitance required is dependent on the acceptable level of
output ripple and any hold-up time requirements. The equations
below provide an easy way to determine the required capacitance
in order to meet the hold-up time requirement and also to meet
the output ripple requirements. The higher of the two values
would be required to be used.
Capacitance required for meeting the hold-up requirement is
calculated using the equation:
CO =
CO
PO
tHOLD-UP
VOUT
VOUT(MIN)
2 # POUT # t HOLD_UP
VOUT2 - VOUT^MIN h2
PFC output capacitance in F.
PFC output power in watts.
Hold-up time specification for the power supply in seconds.
Lowest nominal output voltage of the PFC in volts.
Lowest permissible output voltage of the PFC at the end of hold-up time in volts.
Line-Sense Network
The line-sense network connected to the VOLTAGE MONITOR
pin provides input voltage information to the HiperPFS-2. The
value of this resistance sets the brown-in and brown-out
threshold for the part. A value of 4 MW is recommended for use
with the universal input parts. Only 1% tolerance resistors are
recommended. This resistance value may be modified to adjust
the brown-in threshold if required however change of this value
will affect the maximum power delivered by the part.
A decoupling capacitor of 22 nF is required to be connected
from the VOLTAGE MONITOR pin to the GROUND pin of the
HiperPFS-2 for the universal input parts. This capacitor should
be placed directly at the IC on the circuit board.
Feedback Network
A resistor divider network that provides 6 V at the FEEDBACK
pin at the rated output voltage should be used. The compensation
elements are included with the feedback divider network since
the HiperPFS-2 does not have a separate pin for compensation.
The HiperPFS-2 based PFC has two loops in its feedback. It
has an inner current loop and a low bandwidth outer voltage
loop which ensures high input power factor. The compensation
RC circuit included with the feedback network reduces the
response time of the HiperPFS-2 to fast changes in output
voltage resulting from transient loads.
The recommended circuit and the associated component
values are shown in Figure 15.
D
B+
K
Capacitance required for meeting the low frequency ripple
specification is calculated using the equation:
CO =
fL
∆VO
ηPFC
IO(MAX)
R1
I O^MAX h
Input frequency in Hz.
Peak-peak output voltage ripple in volts.
PFC operating efficiency.
Maximum output current in amps.
Capacitance calculated using the above method should be
appropriately increased to account for ageing and tolerances.
Power Supply for the IC
A 12 V regulated supply should be used for the HiperPFS-2. If
the VCC exceeds 15 V, the HiperPFS-2 may be damaged. In
most applications a simple series pass linear regulator made
using an NPN transistor and Zener diode is adequate since the
HiperPFS-2 only requires approximately 3.4 mA maximum for
its operation.
It is recommended that a 3.3 mF or higher, low ESR ceramic
capacitor be used to decouple the VCC supply. This capacitor
should be placed directly at the IC on the circuit board.
C1
R2
PG
2 # r # fL # DV L # h PFC
VCC
CONTROL
R3
FB
R6
C
HiperPFS-2
PGT
S
V
G
RR
R
CC
CR
D1
R7
R5
R4
C3
C2
PI-6989-041813
Figure 15. Recommended Feedback Circuit.
Resistors R1 to R4 comprise of the main output voltage divider
network. The sum of resistors R1, R2 and R3 is the upper
divider resistor and the lower feedback resistor is R4. Capacitor
C1 is a soft-finish capacitor that reduces output voltage
overshoot at start-up. Capacitor CC is to filter any switching
noise from coupling into the COMPENSATION pin. Resistor R7
and capacitor C3 is the loop compensation network which
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PFS7323-7329
introduces a low frequency zero required to tailor the loop
response to ensure low cross-over frequency and sufficient
phase margin. Resistor R6 isolates the fast portion (resistor
voltage divider network comprising of resistors R1 to R4) and
the slow feedback loop compensator circuit (resistor R7 and
capacitor C3). Diode D1 is included to cover a single point fault
condition wherein capacitor C3 is shorted. In the event C3 is
short-circuited, the FEEDBACK pin is forced below the FBOFF
threshold through diode D1 and subsequently turns the
HiperPFS-2 off. Only a standard recovery diode should be
used for D1. Use of ultrafast or fast recovery diode is not
recommended including small signal diodes (e.g. 1N4148),
which are typically also fast recovery.
The recommended values for the components used are as
follows:
R4 = 60.4 kW
R3 = 1.6 MW
R2 = 787 kW
C1 = 47nF, 200 V X7R/NPO
R6 = 487 kW
R7 = 7.5 kW
C3 = 2.2 mF
Cc = 22 nF
D1 = BAV116 W or 1N4007 (A general purpose standard recovery diode should only be used).
When the above component values are used, the value of
resistor R1 can be calculated using the following equation:
R1 =
VO - 75 - R
3
100 # 10 - 6
The value of resistor R7 will have to be adjusted in some
designs and as a guideline the value from the following
calculation can be used:
R7 = RZ =
PO
^ kX h
1.2 # VO2 # C O
PO Maximum continuous output power in watts
VO Nominal PFC output voltage in volts
CO PFC output capacitance in farads
Improvement in low frequency phase margin can be achieved
by increasing the value of the capacitor C3 however increase in
value of capacitor C3 will result in some increase in overshoot at
the output of the PFC during transient loading and should be
verified.
Heat Sinking and Thermal Design
Figure 16, 17, 18 shows examples of the recommended
assembly for the HiperPFS-2. In these assemblies as shown,
no insulation pad is required and HiperPFS-2 can be directly
connected to heat sink by clip or adhesive thermal material.
The HiperPFS-2 back metal is electrically connected to the heat
sink and the heat sink is required to be connected to the
HiperPFS-2 source terminal in order to reduce EMI.
Figure 16. Heat Sink Assembly – Using Thermally Conductive Adhesive.
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Figure 17. Heat Sink Assembly – With Metal Clip.
Figure 18. Heat Sink Assembly – With Plastic Clip.
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PCB Design Guidelines and Design Example
The line-sense network and the feedback circuit use large
resistance values in order to minimize power dissipation in the
feedback network and the line-sense network. Care should be
taken to place the feedback circuit and the line-sense network
components away from the high-voltage and high current
nodes to minimize any interference. Any noise injected in the
feedback network or the line-sense network will typically
manifest as degradation of power factor. Excessive noise
injection can lead to waveform instability or dissymmetry.
citance in the EMI filter and the differential inductance of the
EMI filter section and the source impedance, works as a filter to
reduce the switching frequency current ripple in the input
current. This capacitor also helps to minimize the loop area of
the switching frequency current loop thereby reducing EMI.
The EMI filter components should be clustered together to improve
filter effectiveness. The placement of the EMI filter components
on the circuit board should be such that the input circuit is
located away from the drain node of the, or the PFC inductor.
A low-loss ceramic dielectric capacitor should be connected
between the cathode of the PFC output diode and the source
terminal of the HiperPFS-2. This ensures that the loop area of
the loop carrying high frequency currents at the transition of
switch-off of the MOSFET is small and helps to reduce radiated
EMI due to high frequency pulsating nature of the diode current
traversing through the loop.
A filter or decoupling capacitor should be placed at the output
of the bridge rectifier. This capacitor together with the X capa-
The connection between the HiperPFS-2 drain node, output
diode drain terminal and the PFC inductor should be kept as
small as possible.
PFC Output
Capacitor
PFC
Output
HiperPFS
PFC
Inductor
Auxiliary Supply for PFC –
from Standby Power Supply
Input
Capacitor
Bridge
Rectifier
Thermistor
Shorting Relay
EMI Filter
AC Input
PI-7010-042313
Figure 19. PCB Layout Example for System Power Supply Consisting of a PFC and a Second Stage Converter.
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PFS7323-7329
During placement of components on the board, it is best to
place the VOLTAGE MONITOR pin, FEEDBACK pin and VCC
pin decoupling capacitors close to the HiperPFS-2 before the
other components are placed and routed. Power supply return
trace from the GROUND pin should be separate from the trace
connecting the feedback circuit components to the GROUND
pin. To minimize effect of trace impedance affecting regulation,
output feedback should be taken directly from the output
capacitor positive terminal. The upper end of the line-sense
resistors should be connected to the high frequency filter
capacitor connected at the output of the bridge rectifier.
Quick Design Checklist
As with any power supply design, all HiperPFS-2 designs
should be verified on the bench to make sure that component
specifications are not exceeded under worst-case conditions.
The following minimum set of tests is strongly recommended:
1. Maximum drain voltage – verify that peak VDS does not
exceed 530 V at lowest input voltage and maximum
overload output power. Maximum overload output power
occurs when the output is overloaded to a level just above
the highest rated load or before the power supply output
voltage starts falling out of regulation. Additional external
snubbers should be used if this voltage is exceeded. In
most designs, addition of a ceramic capacitor in the range of
33 pF and 100 pF connected across the PFC output diode
will reduce the maximum drain-source voltage to a level
below the BVDSS rating. When measuring drain-source
voltage of the MOSFET, a high voltage probe should be
used. When the probe tip is removed, a silver ring in the
vicinity of the probe tip can be seen. This ring is at ground
potential and the best ground connection point for making
noise free measurements. Wrapping stiff wire around the
ground ring and then connecting that ground wire into the
circuit with the shortest possible wire length, and connecting
the probe tip to the point being measured, ensures error-free
measurement. Probe should be compensated according to
probe manufacturers guidelines to ensure error-free
measurement.
2. Maximum drain current – Drain current can be measured
indirectly by monitoring inductor current. A current probe
should be inserted between the bridge rectifier and inductor
connection. At maximum ambient temperature, minimum
input voltage and maximum output load, verify inductor
current waveforms at start-up for any signs of inductor
saturation. When performing this measurement with Sendust
inductor, it is typical to see inductor waveforms that show
exponential increase in current due to permeability drop.
This should not be confused with hard saturation.
3. Thermal check – at maximum output power, minimum input
voltage and maximum ambient temperature; verify that
temperature specifications are not exceeded for the HiperPFS-2,
PFC inductor, output diodes and output capacitors. Enough
thermal margin should be allowed for the part-to-part
variation of the RDS(ON) of HiperPFS-2, as specified in the
data sheet. A maximum package temperature of 100 °C
under worst-case operating conditions is recommended to
allow for these variations.
4. Input PF should improve with load, if performance is found
to progressively deteriorate with loading then that is a sign of
possible noise pickup by the VOLTAGE MONITOR pin circuit
or the feedback divider network and the compensation circuit.
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Absolute Maximum Ratings(2)
DRAIN Pin Peak Current: PFS7323.....................................7.5 A
PFS7324.....................................9.0 A
PFS7325................................... 11.3 A
PFS7326...................................13.5 A
PFS7327...................................15.8 A
PFS7328...................................18.0 A
PFS7329...................................21.0 A
DRAIN Pin Voltage .............................. -0.3 V to 530 V / 540 V(5)
VCC, PG, PGT Pin Voltage ................................... -0.3 V to 15 V
VCC Pin Current............................................................... 25 mA
VOLTAGE MONITOR Pin Voltage ................................-0.3 V to 9 V
FEEDBACK Pin Voltage........................................... -0.3 V to 9 V
COMPENSATION Pin Voltage................................. -0.3 V to 9 V
REFERENCE Pin Voltage ....................................... -0.3 V to 9 V
Storage Temperature ........................................... -65 °C to 150 °C
Junction Temperature(3).................................... -40 °C to 150 °C
Lead Temperature(4) .........................................................260 °C
Notes:
1. All voltages referenced to SOURCE, TA = 25 °C.
2. Maximum ratings specified may be applied one at a time
without causing permanent damage to the product.
Exposure to Absolute Maximum Rating conditions for
extended periods of time may affect product reliability.
3. Normally limited by internal circuitry.
4. 1/16 in. from case for 5 seconds.
5. Limited to a duration ≤ 15 ns and at a drain current ≤ ILIM(TYP).
Qspeed Diode
Peak Repetitive Reverse Voltage (VRRM)
530 V
Average Forward Current (IF(AVG))
TJ(D) = 150 °C
3A
Non-Repetitive Peak Surge Current (IFSM)
60 Hz, ½ cycle, TC(D) = 25 °C
50 A
Non-Repetitive Peak Surge Current (IFSM)
500 μs, TC(D) = 25 °C
130 A
Thermal Resistance
Thermal Resistance: H/L Package:
(qJA)(1) ....................................................103 °C/W
(qJC).................................................. (see Figure 20)
Notes:
1. Controller junction temperature (TJI) may be less than the Internal Power MOSFET Junction Temperature (TJ(M)) and Diode Junction Temperature (TJ(D)).
Symbol
Conditions
SOURCE = 0 V; VCC = 12 V,
TJI = -40 °C to 125 °C
(Note C) (Unless Otherwise Specified)
Min
Typ
Max
Maximum Operating
ON-time
tON(MAX)
0 °C < TJI < 100 °C
30
40
50
Minimum Operating
ON-time
tON(MIN)
0 °C < TJI < 100 °C
See Note A
0.5
Maximum Operating
OFF-time
tOFF(MAX)
0 °C < TJI < 100 °C
30
Minimum Operating
OFF-time
tOFF(MIN)
0 °C < TJI < 100 °C
1
VREF
TJI = 25 °C
See Note A
5.955
6.00
6.045
V
COMPENSATION Pin
Voltage
VC
0 °C < TJI < 100 °C
(In Regulation)
5.88
6.00
6.12
V
FEEDBACK Pin
Current
IFB
340
500
640
nA
Soft-Start Time
tSOFT
TJI = 25 °
Internal Compensation
Frequency
fCOMP
See Note A
Pole (fp)
1
kHz
Av
See Note A
100
V/V
Parameter
Units
Control Functions
Internal Feedback
Voltage Reference
Error-Amplifier Gain
TJI = 25 °C
Normal Operation
1
ms
40
50
3.5
12
ms
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PFS7323-7329
Parameter
Symbol
Conditions
SOURCE = 0 V; VCC = 12 V,
TJI = -40 °C to 125 °C
(Note C) (Unless Otherwise Specified)
Min
Typ
Max
Units
27.50
28.88
mA
Line-Sense/Peak Detector
Brown-In
Threshold Current
IUV+
0 °C < TJI < 100 °C
Brown-Out
Threshold Current
IUV-
0 °C < TJI < 100 °C
22.52
IUV(HYST)
0 °C < TJI < 100 °C
2.5
Soft-Start Brown-Out
Threshold Current
IUV(SS)
TJI = 25 °C
Soft-Start Brown-Out
Time-Out
tUV(SS)
TJI = 25 °C
1000
VOLTAGE MONITOR
Pin Voltage Threshold
VV(THR)
0 °C < TJI < 100 °C
IV = IUV+
1.6
VOLTAGE MONITOR
Pin Short-Circuit
Current
IV(SC)
0 °C < TJI < 100 °C
VV = 6 V
280
mA
VOLTAGE MONITOR
Pin Pre-Soft-Start
Current
IV(SS)
0 °C < TJI < 100 °C
VV = 3 V
5
mA
tREFRESH
TJI = 25 °C
16
60
ms
tBROWN-OUT
TJI = 25 °C
32
60
ms
VOLTAGE MONITOR
Pin Shutdown Current
Threshold
IV(OFF)
0 °C < TJI < 100 °C
VOLTAGE MONITOR
Pin Shutdown Delay
tV(OFF)
TJI = 25 °C
Brown-In/Out
Hysteresis
Line Sample
Refresh Period
Brown-Out Timer
mA
24.50
5.5
mA
20.62
ms
2.3
3.1
110
V
mA
200
65
mA
135
ms
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PFS7323-7329
Parameter
Symbol
Conditions
SOURCE = 0 V; VCC = 12 V,
TJI = -40 °C to 125 °C
(Note C) (Unless Otherwise Specified)
Min
Typ
Max
Units
Current Limit/Circuit Protection
Over-Current
Protection
IOCP
PFS7323L
di/dt = 250 mA/ms
TJI = 25 °C
IV < 48 mA
3.8
4.1
4.3
IV > 59 mA
2.5
2.9
3.2
PFS7324L
di/dt = 300 mA/ms
TJI = 25 °C
IV < 48 mA
4.5
4.8
5.1
IV > 59 mA
3.0
3.5
3.8
PFS7325L
di/dt = 400 mA/ms
TJI = 25 °C
IV < 48 mA
5.5
5.9
6.2
IV > 59 mA
3.7
4.2
4.7
PFS7326H
di/dt = 500 mA/ms
TJI = 25 °C
IV < 48 mA
6.8
7.2
7.5
IV > 59 mA
4.6
5.2
5.7
PFS7327H
di/dt = 650 mA/ms
TJI = 25 °C
IV < 48 mA
8.0
8.4
8.8
IV > 59 mA
5.4
6.0
6.6
PFS7328H
di/dt = 800 mA/ms
TJI = 25 °C
IV < 48 mA
9.0
9.5
9.9
IV > 59 mA
6.0
6.6
7.3
PFS7329H
di/dt = 920 mA/ms
TJI = 25 °C
IV < 48 mA
10.0
10.5
11.0
IV > 59 mA
6.6
7.4
7.9
265
315
365
ms
1
ms
SOA Protection
Time-Out
tOCP
TJI = 25 °C
SOA On-time
tSOA
TJI = 25 °C
See Note A
Leading Edge
Blanking (LEB) Time
tLEB
See Note A
220
ns
Current Limit Delay (ILD)
tIL(D)
See Note A
100
ns
LEB + ILD + Driver Delay
tLEB + tIL(D) +
tDRIVER
TJI = 25 °C
370
470
570
ns
Thermal Shutdown
Temperature
TSHUT
See Note A
110
117
125
°C
Thermal Shutdown
Hysteresis
THYST
See Note A
COMPENSATION Pin
Undervoltage Threshold
CUV
TJI = 25 °C
3
3.5
4
V
COMPENSATION Pin
Undervoltage Delay
tC(UV)
TJI = 25 °C
65
100
135
ms
Feedback Start-Up
Threshold
FBOFF
0 °C < TJI < 100 °C
1.15
1.25
1.45
V
FEEDBACK Pin
Off Delay
tFB(OFF)
0 °C < TJI < 100 °C
°C
49
5
ms
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PFS7323-7329
Parameter
Symbol
Conditions
SOURCE = 0 V; VCC = 12 V,
TJI = -40 °C to 125 °C
(Note C) (Unless Otherwise Specified)
Min
Typ
Max
Units
0.5
1.2
1.65
V
Current Limit/Circuit Protection (cont.)
COMPENSATION Pin
Start-Up Threshold
COFF
0 °C < TJI < 100 °C
COMPENSATION Pin
Off Delay
tC(OFF)
0 °C < TJI < 100 °C
FEEDBACK Pin
Overvoltage Threshold
FBOV
0 °C < TJI < 100 °C
Referenced to VREF
0 °C < TJI < 100 °C Referenced to VREF
ms
5
VREF
VREF
+600 mV +700 mV
VREF
+850 mV
V
VREF
+25 mV
VREF
+160 mV
V
VREF
+90 mV
COMPENSATION Pin
Overvoltage Threshold
COV
FEEDBACK Pin/
COMPENSATION Pin
Overvoltage Delay
tFB(OV)
tC(OV)
0 °C < TJI < 100 °C
FBOV(HYST)
0 °C < TJI < 100 °C
FEEDBACK Pin
Overvoltage Offset
Threshold
FBCOV
0 °C < TJI < 100 °C
Referenced to VC (COMPENSATION Pin)
VC
VC
+225 mV +250 mV
VC
+275 mV
V
FEEDBACK Pin
Undervoltage Offset
Threshold
FBCUV
0 °C < TJI < 100 °C
Referenced to VC (COMPENSATION Pin)
VC
-275 mV
VC
-215 mV
V
FEEDBACK Pin
Charge Current
IFBC
0 °C < TJI < 100 °C
|VFB-VC| > 215 mV
2
Start-Up VCC
(Rising Edge)
VCC+
TJI = 25 °C
9.5
VCC Operating Range
VCC
TJI = 25 °C, See Note A
10.2
Shutdown VCC
(Falling Edge)
VCC-
TJI = 25 °C
9.0
VCC(HYST)
0 °C < TJI < 100 °C
0.2
ICD1
0 °C < TJI < 100 °C
Switching
3.5
ICD2
0 °C < TJI < 100 °C
Not Switching
2.5
VCC Power-Up
Reset Threshold
VCC(POR)
TJI = 25 °C
VCC Power-Up
Reset Current
IVCC(POR)
TJI = 25 °C
VR
0 °C < TJI < 100 °C
RREF = 24.9 kW
FEEDBACK Pin
Overvoltage Hysteresis
VCC Hysteresis
Supply Current
Characteristics
REFERENCE Pin
Voltage
REFERENCE Pin
Threshold
0 °C < TJI < 100 °C Hysterisis
IR
0 °C < TJI < 100 °C
50
1
2
mV
3
+300 mV
VC
-250 mV
ms
V
mA
12
0.5
10.2
V
13.2
V
9.5
V
0.8
V
mA
2.85
3.6
4.25
V
2.5
mA
V
1.240
1.265
1.300
Full Power Mode
(24.9 kW)
48.50
51.00
53.50
Efficiency Power
Mode (49.9 kW)
24.00
mA
25.50
27.00
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PFS7323-7329
Parameter
Symbol
Conditions
SOURCE = 0 V; VCC = 12 V,
TJI = -40 °C to 125 °C
(Note C) (Unless Otherwise Specified)
Min
Typ
Max
Units
Current Limit/Circuit Protection (cont.)
REFERENCE Pin
Off-State Current
Threshold
IR(OFF)
TJI = 25 °C
See Figure 12
Short REFERENCE
Pin to G/S
60
mA
Open
REFERENCE Pin
20
Power Good
Power Good Threshold
Set Reference Current
IPGT
0 °C < TJI < 100 °C
Power Good Delay Time
tPG
TJI = 25 °C
Power Good Internal
Reference Threshold
(Start-Up Threshold)
VPG(H)
0 °C < TJI < 100 °C
Reference to VREF
POWER GOOD Pin
Leakage Current in
Off-State
IPG(OFF)
Power Good
On-State Voltage
Power Good
Comparator Input
Offset Voltage
53.5
mA
100
ms
VREF
-0 mV
V
TJI = 25 °C
VPGT < VREF – 0.3 V
500
nA
VPG(ON)
TJI = 25 °C
IPG = 2 mA
2
V
VPG(OS)
0 °C < TJI < 100 °C
-50
+50
mV
Power Good Threshold
Operating Voltage
VPGT
0 °C < TJI < 100 °C
See Note A
0
13.2
V
Power Good
Operating Voltage
VPG
0 °C < TJI < 100 °C
See Note A
0
13.2
V
48.5
VREF
-600 mV
51.0
VREF
-300 mV
Power MOSFET
PFS7323
PFS7324
PFS7325
ON-State Resistance
RDS(ON)
ID = IOCP × 0.5
and
IV < 48 mA
PFS7326
PFS7327
PFS7328
PFS7329
TJ(M) = 25 °C
0.58
TJ(M) = 100 °C
TJ(M) = 25 °C
1.10
0.49
TJ(M) = 100 °C
TJ(M) = 25 °C
0.39
0.33
0.28
TJ(M) = 100 °C
W
0.33
0.52
0.25
TJ(M) = 100 °C
TJ(M) = 25 °C
0.39
0.62
TJ(M) = 100 °C
TJ(M) = 25 °C
0.46
0.73
TJ(M) = 100 °C
TJ(M) = 25 °C
0.58
0.92
TJ(M) = 100 °C
TJ(M) = 25 °C
0.69
0.29
0.46
0.21
0.25
0.40
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Parameter
Symbol
Conditions
SOURCE = 0 V; VCC = 12 V,
TJI = -40 °C to 125 °C
(Note C) (Unless Otherwise Specified)
Min
Typ
Max
Units
Power MOSFET (cont.)
Effective Output
Capacitance
Breakdown Voltage
Breakdown Voltage
Temperature Coefficient
Off-State Drain Current
Leakage
COSS
BVDSS
176
PFS7324
210
PFS7325
265
PFS7326
312
PFS7327
320
PFS7328
420
PFS7329
487
TJ(M) = 25 °C, VCC = 12 V
ID = 250 mA, VFB = VV = VC = 0 V
530
BVDSS(TC)
IDSS
Turn-Off Voltage
Rise Time
tR
Turn-On Voltage
Fall Time
tF
Start-Up Time Delay
TJ(M) = 25 °C
VGS = 0 V,
VDS = 0 to 80% VDSS
(See Note A)
PFS7323
V
0.048
TJ(M) = 100 °C
VDS = 80%
BVDSS
VCC = 12 V
VFB=VV=VC=0
%/°C
PFS7323
TJ(M) = 100 °C
80
PFS7324
TJ(M) = 100 °C
100
PFS7325
TJ(M) = 100 °C
120
PFS7326
TJ(M) = 100 °C
150
PFS7327
TJ(M) = 100 °C
170
PFS7328
TJ(M) = 100 °C
200
PFS7329
TJ(M) = 100 °C
235
mA
50
See Notes A, B, C
tSTART-DELAY
pF
ns
100
0 °C < TJI < 100 °C
See Note A, B
2
6
10
ms
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PFS7323-7329
Parameter
Symbol
Conditions
SOURCE = 0 V; VCC = 12 V,
TJI = -40 °C to 125 °C
(Note C) (Unless Otherwise Specified)
Min
Typ
Max
Units
Qspeed Diode
DC Characteristics
Reverse Current
Forward Voltage
Junction Capacitance
IR(D)
VF
CJ
VR = 530 V,
TJ(D) = 25 °C
0.4
mA
VR = 530 V,
TJ(D) = 100 °C
0.07
mA
IF = 3 A,
TJ(D) = 25 °C
1.55
IF = 3 A,
TJ(D) = 100 °C
1.47
VR = 10 V, 1 MHz
18
V
pF
Dynamic Characteristics
Reverse Recovery
Time
tRR
di/dt = 200 A/μs,
VR = 400 V
IF = 3 A
Reverse Recovery
Charge
QRR
di/dt = 200 A/μs,
VR = 400 V
IF = 3 A
Maximum Reverse
Recovery Current
IRRM
di/dt = 200 A/μs,
VR = 400 V
IF = 3 A
S
di/dt = 200 A/μs,
VR = 400 V
IF = 3 A
Softness Factor = tB/tA
TJ(D) = 25 °C
25
TJ(D) = 100 °C
31
TJ(D) = 25 °C
33.5
TJ(D) = 100 °C
57
TJ(D) = 25 °C
1.9
TJ(D) = 100 °C
2.5
TJ(D) = 25 °C
1
TJ(D) = 100 °C
0.45
ns
nC
A
-
NOTES:
A. Not tested parameter. Guaranteed by design.
B. Tested in typical Boost PFC application circuit with 22 nF capacitor between VOLTAGE MONITOR and SIGNAL GROUND pins,
and 4 MΩ resistor from rectified line to the VOLTAGE MONITOR pin.
C. Normally limited by internal circuitry.
25
www.powerint.com
Rev. B 06/13
PFS7323-7329
Thermal Resistance θJC (°C/W)
3
PI-6992-032813
Typical Performance Characteristics
Thermal Resistance of Internal Qspeed Diode is = 5.2 °C/W for all devices.
Thermal Resistance of Internal Power MOSFET shown below.
2.5
2
1.5
1
0.5
0
0 PFS7323
PFS7324
PFS7325
PFS7326
PFS7327
PFS7328
PFS7329
Figure 20. Thermal Resistance (θJC ).
26
Rev. B 06/13
www.powerint.com
www.powerint.com
1
5
6
10 11
END VIEW
0.628 (15.95) Ref.
0.060 (1.52) Ref.
9
FRONT VIEW
7 8
Pin 1 I.D.
0.653 (16.59)
0.647 (16.43)
0.038 (0.97)
3 4
0.019 (0.48) Ref.
A
2
13 14
16
2
0.140 (3.56)
0.120 (3.05)
Detail A
0.016 (0.41) 13×
0.011 (0.28)
0.020 M 0.51 M C
3
0.021 (0.53)
0.019 (0.48)
0.048 (1.22)
0.046 (1.17)
10° Ref.
All Around
0.056 (1.42) Ref.
0.325 (8.25)
0.320 (8.13)
B
SIDE VIEW
0.081 (2.06)
0.077 (1.96)
0.027 (0.70)
0.023 (0.58)
0.020 (0.50)
0.118 (3.00)
0.047 (1.19)
0.016 (0.41)
Ref.
0.290 (7.37)
Ref.
C
eSIP-16D (H Package)
3
Dimensions in inches, (mm).
All dimensions are for reference.
PCB FOOT PRINT
0.118 (3.00)
0.029 Dia Hole
0.062 Dia Pad
BACK VIEW
4
0.024 (0.61) 13×
0.019 (0.48)
0.010 M 0.25 M C A B
0.207 (5.26)
0.187 (4.75)
0.208 (5.27)
Ref.
Notes:
1. Dimensioning and tolerancing per ASME Y14.5M-1994.
2. Dimensions noted are determined at the outermost
extremes of the plastic body exclusive of mold flash,
tie bar burrs, gate burrs, and interlead flash, but
including any mismatch between the top and bottom
of the plastic body. Maximum mold protrusion is 0.007
[0.18] per side.
3. Dimensions noted are inclusive of plating thickness.
4. Does not include interlead flash or protrusions.
5. Controlling dimensions in inches (mm).
PI-6972-022713
0.076 (1.93)
0.038 (0.97)
0.012 (0.30) Ref.
0.076 (1.93)
0.519 (13.18)
Ref.
0.524 (13.31) Ref.
PFS7323-7329
Rev. B 06/13
27
Rev. B 06/13
1
5
6
END VIEW
0.628 (15.95) Ref.
0.060 (1.52) Ref.
11
13
0.056 (1.42) Ref.
9
10
FRONT VIEW
Typ. 9 Places
7
8
Pin 1 I.D.
0.038 (0.97)
3
4
0.019 (0.48) Ref.
A
2
0.653 (16.59)
0.647 (16.43)
14
16
2
0.094 (2.40)
Detail A
0.048 (1.22)
0.046 (1.17)
0.021 (0.53)
0.019 (0.48)
10° Ref.
All Around
R0.012 (0.30)
Typ., Ref.
0.016 (0.41) 13×
0.011 (0.28)
0.020 M 0.51 M C
3
0.325 (8.25)
0.320 (8.13)
B
0.081 (2.06)
0.077 (1.96)
SIDE VIEW
0.027 (0.70)
0.023 (0.58)
0.020 (0.50)
0.128 (3.26)
0.122 (3.10)
0.144 (3.66) Ref.
0.047 (1.19) Ref.
0.050 (1.26) Ref.
0.290 (7.37)
Ref.
C
eSIP-16G (L Package)
14
13
11
10
3
5
4
4
3
1
0.173 (4.39)
0.163 (4.14)
0.024 (0.61) 13×
0.019 (0.48)
0.010 M 0.25 M C A B
7
6
0.076 (1.93)
0.038 (0.97)
BACK VIEW
9
8
Dimensions in inches, (mm).
All dimensions are for reference.
PCB FOOT PRINT
0.094 (2.40)
0.029 Dia Hole
0.062 Dia Pad
16
0.208 (5.27)
Ref.
Notes:
1. Dimensioning and tolerancing per ASME Y14.5M-1994.
2. Dimensions noted are determined at the outermost
extremes of the plastic body exclusive of mold flash,
tie bar burrs, gate burrs, and interlead flash, but
including any mismatch between the top and bottom
of the plastic body. Maximum mold protrusion is 0.007
[0.18] per side.
3. Dimensions noted are inclusive of plating thickness.
4. Does not include interlead flash or protrusions.
5. Controlling dimensions in inches (mm).
PI-6791-022713
Typ. 3 Pieces
0.076 (1.93)
0.079 (1.99)
0.069 (1.74)
0.524 (13.31) Ref.
PFS7323-7329
28
www.powerint.com
PFS7323-7329
Part Ordering Information
Part Number
Option
Quantity
PFS7323L
Tube
30
PFS7324L
Tube
30
PFS7325L
Tube
30
PFS7326H
Tube
30
PFS7327H
Tube
30
PFS7328H
Tube
30
PFS7329H
Tube
30
Part Marking Information
• HiperPFS-2 Product Family
• PFS-2 Series Number
• Package Identifier
PFS 7323 L
L
Plastic eSIP, L Bend
H
Plastic eSIP
29
www.powerint.com
Rev. B 06/13
Revision
Notes
Date
A
Initial Release.
06/03/13
B
Updated tBROWN-OUT. Updated Minimum IOCP for PFS7329H.
06/10/13
For the latest updates, visit our website: www.powerint.com
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Integrations does not assume any liability arising from the use of any device or circuit described herein. POWER INTEGRATIONS MAKES
NO WARRANTY HEREIN AND SPECIFICALLY DISCLAIMS ALL WARRANTIES INCLUDING, WITHOUT LIMITATION, THE IMPLIED
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by one or more U.S. and foreign patents, or potentially by pending U.S. and foreign patent applications assigned to Power Integrations. A
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