NSC LM5027

LM5027
Voltage Mode Active Clamp Controller
General Description
Features
The LM5027 pulse-width modulation (PWM) controller contains all of the features necessary to implement power converters utilizing the Active Clamp / Reset technique. With the
active clamp technique, higher efficiencies and greater power
densities can be realized compared to conventional catch
winding or RDC clamp / reset techniques. Three control outputs are provided: the main power switch control (OUTA), the
active clamp switch control (OUTB), and secondary side synchronous rectifier control (OUTSR). The timing between the
control outputs is adjustable with external resistors that program internal precision timers. This controller is designed for
high-speed operation including an oscillator frequency range
up to 1 MHz and total PWM propagation delays less than 50
ns. The LM5027 includes a high-voltage startup regulator with
a maximum input voltage rating of 105V. Additional features
include Line Under Voltage Lockout (UVLO), separate softstart of main and synchronous rectifier outputs, a timer for
hiccup mode current limiting, a precision reference, and thermal shutdown.
■
■
■
■
■
■
■
■
■
■
■
■
■
Voltage-Mode control
Line feed-forward PWM ramp
Internal 105V rated start-up bias regulator
Programmable line Under-Voltage Lockout (UVLO) with
adjustable hysteresis
Versatile dual mode over-current protection
Programmable volt-second limiter
Programmable soft-start
Programmable synchronous rectifier soft-start and stop
Precise 500mV over-current comparator
Current sense leading edge blanking
Programmable oscillator with 1 MHz maximum frequency
and synchronization capability
Precision 5V reference
Programmable time delays between outputs
Packages
■ eTSSOP-20
Typical Application Circuit
30099001
Simplified Active Clamp Converter
© 2009 National Semiconductor Corporation
300990
www.national.com
LM5027 Voltage Mode Active Clamp Controller
August 18, 2009
LM5027
Connection Diagram
30099002
20-Lead eTSSOP
Ordering Information
Order Number
Package Type
NSC Package Drawing
Package Marking
Supplied As
LM5027MH
eTSSOP-20
MXA20A
LM5027MH
73 units per Rail
LM5027MHX
eTSSOP-20
MXA20A
LM5027MH
2500 Units per Tape and
Reel
Pin Descriptions
Pin
Name
1
VIN
Description
Application Information
Input voltage source
Input to the Start-up Regulator. Operating input range is 13V to 90V.
The Absolute Maximum Rating is 105V. For power sources outside of
this range, the LM5027 can be biased directly at VCC by an external
regulator.
2
RAMP
Feed-forward modulation ramp
An external RC circuit from VIN sets the PWM ramp slope. This pin is
discharged at the conclusion of every cycle by an internal FET. An
internal comparator terminates the PWM pulse if the RAMP pin
exceeds 2.5V thus limiting the maximum volt-second product to the
transformer primary.
3
TIME3
Overlap delay 3
An external resistor sets the overlap delay for the active clamp output.
The RTIME3 resistor connected between TIME3 and AGND sets the
OUTA turn-off (falling edge) to OUTB turn-on (falling edge) pulse delay.
See Fig. 9.
4
TIME2
Overlap delay 2
An external resistor sets the overlap delay for the OUTSR output. The
RTIME2 resistor connected between TIME2 and AGND sets the OUTA
turn-off (falling edge) to OUTSR turn-on (rising edge) pulse delay. See
Fig. 9.
5
TIME1
Overlap delay 1
An external resistor sets the overlap delay for the active clamp output.
The RTIME1 resistor connected between TIME1 and AGND sets the
OUTB and OUTSR turn-off to OUTA turn-on pulse delay. See Fig. 9.
6
AGND
Analog ground
Connect directly to Power Ground.
7
RT
www.national.com
Oscillator frequency control and sync Normally biased at 2V by an internal amplifier. An external resistor
clock input
connected between RT and AGND sets the internal oscillator
frequency. The internal oscillator can be synchronized to an external
clock with a frequency higher than the free running frequency set by
the RT resistor.
2
Name
Description
Application Information
8
COMP
Input to the pulse width modulator
An external opto-coupler connected to the COMP pin sources current
into an internal NPN current mirror. The PWM duty cycle is at its
maximum value with zero input current, while 1mA reduces the duty
cycle to zero. The current mirror improves the frequency response by
reducing the ac voltage across the opto-coupler detector transistor.
9
REF
Reference Output
Output of a 5V reference. Maximum output current is 10 mA. Locally
decouple with a 0.1 µF capacitor.
10
OUTB
Output driver
Control output of the active clamp PFET gate. Capable of 1A peak
source and sink current.
11
OUTA
Output driver
Control output of the main PWM NFET gate. Capable of 2A peak
source and sink current.
12
OUTSR
Output driver
Control output of the secondary side synchronous rectifier FET gates.
Capable of 3A peak source and sink current.
13
PGND
Power ground
Connect directly to Analog Ground
14
VCC
Start-up regulator output
Output of the internal high voltage start-up regulator. Regulated at 9.5V
during start-up and 7.5V during run mode. If the auxiliary winding raises
the voltage on this pin above the regulation set point, the internal startup regulator will shutdown, thus reducing the IC power dissipation.
15
CS
Current sense input
Current sense input for cycle-by-cycle current limiting. If the CS pin
exceeds 500mV the output pulse will be terminated, entering cycle-bycycle current limit. An internal switch holds CS low for 100 ns after
OUTA switches high to blank leading edge transients.
16
SS
Soft-start Input
An internal 22 µA current source charges an external capacitor to set
the soft-start rate.
17
RES
Restart timer
If cycle-by-cycle current limit is reached during any cycle, a 22 µA
current is sourced into the RES capacitor. If the RES capacitor voltage
charges to 1.0V, a hiccup sequence is initiated. The SS and SSSR
capacitors are discharged and the control outputs are disabled. The
voltage on the RES capacitor is ramped between 4V and 2V eight
times. After the eighth cycle, the SS capacitor is released and the
normal start-up sequence begins.
18
SSSR
Soft-start for synchronous rectifier
output.
An external capacitor and an internal 25 µA current source sets the
soft-start and soft-stop ramps for the synchronous rectifier output
(OUTSR).
19
OTP
Over-Temperature Protection
The OTP comparator can be used for over-temperature shutdown
protection with an external NTC thermistor voltage divider setting the
shutdown temperature. The OTP comparator threshold is 1.25V.
Hysteresis is set by an internal current source that sources 20 µA into
the external resistor divider when the OTP pin voltage is above the
threshold.
20
UVLO
Line under-voltage lockout
An external voltage divider from the power source sets the shutdown
and standby comparator levels. When UVLO reaches the 0.4V
threshold, the VCC and REF regulators are enabled. When UVLO
reaches the 2.0V threshold, the SS pin is released and the device
enters the active mode. Hysteresis is set by an internal current source
that pulls 20 µA from the external resistor divider when the UVLO pin
is below the 2.0V threshold.
Exposed pad, underside of package
No electrical contact to the LM5027 integrated circuit. Connect to
system ground plane for reduced thermal resistance.
EP
3
www.national.com
LM5027
Pin
LM5027
ESD Rating (Note 3)
Human Body Model
Storage Temperature Range
Junction Temperature
Absolute Maximum Ratings (Note 1)
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
VIN to GND
VCC to GND
UVLO to GND
All other inputs to GND
COMP Input Current
COMP, REF (Note 2)
-0.3V to 105V
-0.3V to 16V
-0.3 to 8V
-0.3 to 7V
10 mA
Operating Ratings
2kV
-55°C to 150°C
150°C
(Note 1)
VIN
VCC
Operating Junction Temperature
13 to 90V
8 to 15V
-40°C to +125°C
Electrical Characteristics
Limits in standard type are for TJ = 25°C only; limits in boldface type apply over the
junction temperature range of –40°C to +125°C. Unless otherwise specified, the following conditions apply: VIN = 48V, VCC = 10V,
RT= 27.4K , No Load on OUTA, OUTB and OUTSR unless otherwise stated.
Symbol
Parameter
Conditions
Min
Typ
Max
Units
6
mA
310
650
µA
9.9
VIN SUPPLY
Ibias
VIN Operating Current
COMP and VCC Open, UVLO and OTP = 3V
VIN Shutdown Current
UVLO = 0V, Vin = 100 V
VCC REGULATOR
VccReg
VCC Regulation
No Load (SS<4V)
9.1
9.5
VCC Current Limit
VCC=9.5V
55
65
mA
V
VCC Regulator load regulation
IVCCREG 0 to 15 mA
75
mV
VCC Under-voltage Lockout
Voltage
Positive going VCC
VccReg
–180mV
VccReg –
100mV
V
VCC Regulation
No Load
7.3
7.5
7.7
V
VCC Under-voltage Lockout
Voltage
Negative going Vcc
5.7
6.0
6.3
V
VCC Supply Current (Icc)
Supply current into VCC form an external
source, CGATE = OPEN, VCC 10V
5.5
mA
REFERENCE SUPPLY
Reference Voltage
IREF = 0mA
Reference Voltage Regulation
IREF= 0 to 10mA
4.85
Reference Current Limit
REF Under-voltage Threshold
10
UVLO >0.4V, VCC >9.5V
5.0
5.15
V
10
20
mV
17.5
mA
V
3.8
UVLO/OTP THRESHOLDS
UVLO Threshold
1.9
2
2.1
V
20
25
µA
UVLO Hysteresis Current
UVLO
UVLO Shutdown Threshold
ULVLO voltage falling
0.3
V
UVLO Standby Enable
Threshold
UVLO voltage rising
0.4
V
OTP Shutdown Threshold
OTP rising
OTP Hysteresis Current
16
1.21
1.25
1.29
V
OTP
15
20
24
µA
SS = 0V
17
22
26
µA
SS Rising Threshold for SSSR
charge current enable
3.8
4
4.2
V
SSSR Charging Current Source SSSR = 0V, SS>4V
18
25
30
µA
SSSR Discharge Current
Source in Soft Stop
14
20
26
µA
SSSR Falling Threshold for SS
Soft Stop
1.5
2.2
3.0
V
SOFT-START
SS Charging Current Source
SS output low voltage
Sinking 100 µA UVLO = 0
SSSR output low voltage
www.national.com
4
120
mV
100
mV
Parameter
Conditions
Min
Typ
Max
Units
200
220
kHz
490
550
kHz
150
ns
OSCILLATOR
Frequency1
RT = 27.4 kΩ
180
Frequency2
RT = 11 kΩ
420
Sync Threshold
2.85
Sync Pulse Width
15
Sync Frequency Range
160
V
kHz
PWM COMPARATORS
Delay to Output
50
COMP to PWM Offset
Duty Cycle Maximum
ns
1.0
OUTA, OUT_A = Tdelay_min
V
%
90
CURRENT LIMIT RESTART (RES Pin)
RES Threshold
1.1
Charge Source Current Level 1 VRES < 1.0V
22
25
µA
5.0
6.5
µA
5
7
µA
550
mV
Charge Source Current Level 2 4.0V < VRES > 1.0V
4
Discharge Current Source
VRES ramping down
4
Ratio of RES Threshold to SS
Low
VRES > 1V, Hiccup counter
V
125
CURRENT LIMIT
CS prop
Cycle by cycle sense voltage
threshold
RAMP = 0
Current limit propagation delay
CS step from 0 to 0.6V time to onset of OUTA
transition (90%) Cgate = 0pen
30
ns
RDS(ON)
5
Ω
450
500
VOLTAGE FEED-FORWARD (RAMP Pin)
RAMP Discharge Device
VOLT-SECOND CLAMP
Ramp Clamp Level
Delta RAMP measured from onset of OUTA
to Ramp peak. Comp = 5V
2.3
2.5
2.6
V
0.15
0.5
V
OUTA GATE DRIVER
VOL
OUTA Low-state Output Voltage IOUTA = 100 mA
VOH
OUTA High-state Output
Voltage
IOUTA = -100 mA, VOHL = VCC -VLO
OUTA Rise Time
0.21
V
C-load = 1000 pF
10
ns
0.35
OUTA Fall Time
C-load = 1000 pF
13
ns
IOHL
Peak OUTA Source Current
VOUTA = 0V (VCC = 10V)
2
A
IOLL
Peak OUTA Sink Current
VOUTA = VCC= 10V
2
A
OUTB GATE DRIVER
VOL
OUTB Low-state Output Voltage IOUTB = 100 mA
0.2
VOH
OUTB High-state Output
Voltage
IOUTB = -100 mA, VOHL = VCC -VLO
OUTB Rise Time
OUTB High Side Fall Time
0.4
V
0.31
V
C-load = 1000 pF
15
ns
C-load = 1000 pF
13
ns
Peak OUTB Source Current
VOUTB = 0V (VCC = 10V)
1
A
Peak OUTB Source Current
VOUTB = VCC= 10V
1
A
5
0.5
www.national.com
LM5027
Symbol
LM5027
Symbol
Parameter
Conditions
Min
Typ
Max
Units
0.1
0.2
V
OUTSR GATE DRIVER
VOL
OUTSR Low-state Output
Voltage
IOUTSR = 100 mA
VOH
OUTSR High-state Output
Voltage
IOUTSR = -100 mA, VOHL = VCC -VLO
OUTSR Rise Time
0.11
V
C-load = 1000 pF
12
ns
0.25
OUTSR High Side Fall Time
C-load = 1000 pF
10
ns
IOHH
Peak OUTSR Source Current
VOUTSR = 0V (VCC = 10V)
3
A
IOLH
Peak OUTSR Source Current
VOUTSR = VCC= 10V
3
A
OUTPUT TIMING CONTROL
T1
Delay Leading Range
RTIME1=10 kΩ – 100 kΩ
30
T1
Delay Leading Accuracy
RTIME1 = 33.2 kΩ
75
T2
Delay Trailing Range
RTIME2 = 10 kΩ – 100 kΩ
30
T2
Delay Trailing Accuracy
RTIME2 = 28.7 kΩ
75
T3
Delay Leading Range
RTIME3 = 10 kΩ – 100 kΩ
30
T3
Delay Leading Accuracy
RTIME3 = 29.4 kΩ
75
100
150
100
100
300
ns
125
ns
300
ns
125
ns
300
ns
125
ns
THERMAL
tsd
Thermal Shutdown Temp.
165
°C
Thermal Shutdown Hysteresis
25
°C
RJA
Junction to Ambient
40
°C/W
RJC
Junction to Exposed Pad
4
°C/W
Note 1: Absolute Maximum Ratings are limits beyond which damage to the device may occur. Operating Ratings are conditions under which operation of the
device is intended to be functional. For guaranteed specifications and test conditions, see the Electrical Characteristics.
Note 2: It is not recommended that external power sources be connected to these pins.
Note 3: The human body model is a 100 pF capacitor discharged through a 1.5 kΩ resistor into each pin.
www.national.com
6
LM5027
Typical Performance Characteristics
VCC and VREF vs. VIN
VCC vs. ICC
30099024
30099025
VREF vs. IREF
Oscillator Frequency vs RT Resistor
30099026
30099027
Oscillator Frequency vs Temperature
Time1 Delay vs RTIME1 (kΩ)
30099028
30099029
7
www.national.com
LM5027
Time2 Delay vs RTIME2 (kΩ)
Time3 Delay vs RTIME3 (kΩ)
30099030
30099031
Time1 Delay vs Temperature
RTIME1 = 33.2 kΩ
Time2 Delay vs Temperature
RTIME2 = 28.7 kΩ
30099032
30099033
Time3 Delay vs Temperature
RTIME3 = 29.4 kΩ
SS Pin Current vs Temperature
30099035
30099034
www.national.com
8
RES Pin Charging Current Level 1 vs Temperature
30099036
30099037
9
www.national.com
LM5027
SSSR Pin Charging Current vs Temperature
LM5027
Block Diagram
30099003
FIGURE 1. Simplified Block Diagram
www.national.com
10
The LM5027 PWM controller contains all the features necessary to implement power converters utilizing the Active Clamp
Reset technique with synchronous rectification. The device is
configured to control a P-Channel clamp switch. With the active clamp technique higher efficiencies and greater power
densities can be realized compared to conventional catch
winding or RDC clamp / reset techniques. The LM5027 provides three gate driver outputs: one to drive the primary side
MOSFET (OUTA), one for the active clamp P-Channel MOSFET (OUTB), and one output to drive the synchronous rectifier through an isolation interface (OUTSR). This controller is
designed for high-speed operation including an oscillator frequency range up to 1 MHz and total PWM and current sense
propagation delay less than 50 ns. The LM5027 includes a
high-voltage start-up regulator that operates over a wide input
range of 13V to 90V. Additional features include: Line UnderVoltage lockout (UVLO), soft-start/soft-stop, oscillator with
synchronization capability, cycle-by-cycle current limit, hiccup
mode fault protection with adjustable delay, precision reference, and thermal shutdown.
Reference
The REF pin is the output of a 5V linear regulator that can be
used to bias an opto-coupler transistor and external housekeeping circuits. The regulator output is internally current
limited to 10 mA.
High Voltage Start-Up Regulator
The LM5027 contains an internal high voltage start-up regulator that allows the input pin (VIN) to be connected directly
to the line voltage. The regulator output is internally current
limited to 55mA. When the UVLO pin potential is greater than
0.4V, the VCC regulator is enabled to charge an external capacitor connected to the VCC pin. The VCC regulator provides power to the voltage reference (REF) and the gate
drivers (OUTA, OUTB, and OUTSR). The controller outputs
are enabled when the voltage on the VCC pin reaches the
regulation point of 9.5V, the internal voltage reference (REF)
reaches its regulation point of 5V, the UVLO pin voltage is
greater than 2V, and the OTP pin voltage is greater than
1.25V. The outputs will remain enabled unless one of the following conditions occurs, VCC falls below 6.0V, UVLO is
below 2.0 V, or the OTP pin falls below 1.25V. The value selected for the VCC capacitor depends on the total system
design and the start-up characteristics. The recommended
capacitance range for the VCC regulator is 0.1 µF to 100 µF.
In a typical application, an auxiliary transformer winding is
connected through a diode to the VCC pin. This winding must
raise the VCC voltage above the VCC regulation set point to
shut off the internal start-up regulator. The LM5027 lowers the
VCC regulation set point from 9.5V to 7.5V after the output of
the first OUTSR drive pulse. Powering VCC from an auxiliary
winding improves efficiency while reducing the controller
power dissipation. When the converter auxiliary winding is inactive, external current draw on the VCC line should be limited
so the power dissipation in the start-up regulator does not exceed the maximum power dissipation of the LM5027 package. An external start-up regulator or other bias rail can be
used instead of the internal start-up regulator by connecting
the VCC and the VIN pins together and feeding the external
bias into the two pins.
Cycle-by-Cycle Current Limit
The CS pin is to be driven by a signal representative of the
transformer primary current. If the voltage on the CS pin exceeds 0.5V, the current sense comparator terminates the
output driver pulse, with the duty cycle determined by the current sense comparator instead of the PWM comparator. A
small R-C filter connected to the CS pin and located near the
controller is recommended to suppress noise. An internal
5Ω MOSFET discharges the external current sense filter capacitor at the conclusion of every cycle. The discharge MOSFET remains on for an additional 30 ns after either OUTA
driver switches high to blank leading edge transients in the
current sensing circuit. Discharging the CS pin filter each cycle and blanking leading edge spikes reduces the filtering
requirements and improves the current sense response time.
The current sense comparator is very fast and may respond
to short duration noise pulses. Layout considerations are critical for the current sense filter and sense resistor. The capacitor associated with the CS filter must be placed very close
to the device and connected directly to the CS and AGND
pins. If a current sense transformer is used, both leads of the
transformer secondary should be routed to the filter network,
which should be located close to the IC. When designing with
a current sense resistor, all of the noise sensitive low power
ground connections should be connected together near the
AGND pin, and a single connection should be made to the
power ground (sense resistor ground point).
Restart Time Delay (Hiccup Mode)
The LM5027 provides a current limit restart timer to disable
the outputs and force a delayed restart (hiccup mode) if a
current limit condition is repeatedly sensed. The number of
cycle-by-cycle current limit events required to trigger the
restart is programmable by the external capacitor at the RES
pin. During each PWM cycle, the LM5027 either sources or
sinks current from the RES pin capacitor. If no current limit is
detected during a cycle, a 5 µA current sink is enabled to pull
the RES pin to ground. If a current limit is detected, the 5 µA
current sink is disabled and a 22 µA current source causes
Line Under-Voltage Detector
The LM5027 contains a dual level line Under Voltage Lock
Out (UVLO) circuit. When the UVLO pin voltage is greater
than 0.4V but less than 2.0V, the controller is in a standby
mode. In the standby mode the VCC and REF bias regulators
are active while the controller outputs are disabled. This feature allows the UVLO pin to be used as a remote enable/
disable function. Pulling the UVLO pin below the 2.0V thresh11
www.national.com
LM5027
old initiates a soft-stop sequence described later in this document. There is 100mV of hysteresis provided in the 0.4V
shutdown comparator. When the VCC and REF outputs exceed their respective under-voltage thresholds and the UVLO
pin voltage is greater than 2.0V and the OTP pin voltage is
greater than 1.25V, the outputs are enabled and normal operation begins. An external set-point voltage divider from the
VIN to GND can be used to set the minimum operating voltage
of the converter. The divider must be designed such that the
voltage at the UVLO pin will be greater than 2.0V when Vin is
in the desired operating range. If the under-voltage threshold
is not met, all three outputs are disabled. UVLO hysteresis is
accomplished with an internal 20 µA current sink that is
switched on or off into the impedance of the set-point divider.
When the UVLO pin voltage exceeds 2.0V threshold, the current sink is deactivated to quickly raise the voltage at the
UVLO pin. When the UVLO pin voltage falls below the 2.0V
threshold, the current sink is turned on causing the voltage at
the UVLO pin to quickly fall .
Detailed Operating Description
LM5027
the voltage at the RES pin to gradually increase. If the RES
voltage reaches the 1.0V threshold, the following restart sequence occurs (also see Figure 2).
• The SS and SSSR capacitors are fully discharged.
• The RES 20 µA current source is turned-off and the 5 µA
current source is turned-on.
• The voltage on the RES pin is allowed to charge up to 4.0V.
• When voltage on the RES pin reaches 4.0V the 5 µA current
source is turned-off and a 5 µA current sink is turned-on,
ramping the voltage on the RES capacitor down to 2.0V.
• The RES capacitor voltage is ramped between 4.0V and
2.0V eight times.
• When the counter reaches eight, the RES pin voltage is
pulled low and the Soft-Start capacitor is released to begin a
soft-start sequence. The SS capacitor voltage slowly increases. When the SS voltage reaches 1.0V, the PWM comparator
will produce the first narrow output pulse at OUTA.
• When the SS voltage reaches 4.0V the capacitor on the
SSSR pin is released and is charged with a 25 µA current
source, soft-starting the free-wheeling synchronous rectifier.
• If the overload condition persists after restart, cycle-by-cycle
current limiting will begin to increase the voltage on the RES
capacitor again, repeating the hiccup mode sequence.
• If the overload condition no longer exists after restart, the
RES pin will be held at ground by the 5 µA current sink and
normal operation resumes.
30099004
FIGURE 2. Restart and Soft-Start Delay Timing
www.national.com
12
The soft-start circuit allows the regulator to gradually increase
its output voltage until the steady state operating point is
reached; thereby reducing start-up stresses and surge currents. When bias power is supplied to the LM5027, the SS pin
capacitor is discharged by an internal MOSFET. When the
voltages on the UVLO, OTP, VCC, and REF pins reach the
operating thresholds, the soft-start capacitor is released and
is charged with a 22 µA current source. When the SS pin voltage reaches 1V, output pulses commence with a slowly increasing duty cycle (refer to Figure 3, Figure 4 and Figure
5). The voltage on the SS pin eventually increases to 5V, while
the voltage at the PWM comparator is limited to the level required for regulation as determined by the voltage feedback
loop via the COMP pin. When the soft-start voltage reaches
4.0V, the capacitor on the SSSR pin is released and charged
with a 25 µA current source (refer to Figure 3, Figure 4 and
Figure 5) . When the SSSR pin voltage reaches approximately 2.5V (refer to Figure 6), the internal synchronous rectifier
PWM circuit gradually increases the synchronous rectifier
drive duty cycle (OUTSR) in proportion the rising SSSR pin
voltage. Delaying the start of the SSSR gate drive pulses until
Soft-Stop
If the UVLO pin voltage falls below the 2.0V standby threshold, but above the 0.4V shutdown threshold, the synchronous
rectification soft-start capacitor is discharged with a 20 µA
current source which gradually disables the synchronous rectifiers (refer to Figure 4). After the SSSR capacitor has been
discharged to 2.0V the soft-start and synchronous rectification soft-start capacitors are quickly discharged to ground to
terminate PWM pulses at OUTA ,OUTB, and OUTSR. The
PWM pulses may cease before the SSSR voltage reduces
the synchronous rectifier duty cycle if the VCC or REF voltage
drops below the respective under-voltage thresholds during
the soft-stop process. This soft-stop method of turning off the
converter prevents oscillations in the synchronous rectifiers
during a shutdown sequence.
30099005
FIGURE 3. Soft-Start Timing
13
www.national.com
LM5027
after the main soft-start is completed allows the output voltage
to reach regulation before the synchronous rectifiers begins
operation. This delay prevents the synchronous rectifier from
sinking current from the output in applications where the output voltage may be pre-biased.
Soft-Start
LM5027
30099006
FIGURE 4. Soft-Start/Soft-Stop Timing
30099007
FIGURE 5. Soft-Start and Drive Enable
www.national.com
14
LM5027
30099008
FIGURE 6. Soft-Start Synchronous Rectifier Timing
External Over-Temperature
Protection
An external set-point voltage divider between the REF, OTP,
and AGND pins, as shown in Figure 7, is one method to implement over-temperature protection shutdown. Typically a
NTC thermistor is installed as the lower device of the voltage
divider. The divider must be designed such that the voltage
at the OTP pin will be greater than 1.25V when there is not
an over-temperature condition, and the OTP pin must drop
below 1.25V during an over-temperature event. OTP hysteresis is accomplished with an internal 20 µA current source that
is switched on or off into the impedance of the external setpoint divider. When the OTP pin voltage exceeds 1.25V
threshold, the current source is activated to quickly raise the
voltage at the OTP pin. When the OTP pin voltage falls below
the 1.25V threshold, the current source is turned off causing
the voltage at the OTP pin to quickly fall. When OTP falls below 1.25V the LM5027 will go through a soft-stop turn-off
sequence.
30099009
FIGURE 7. External OTP Protection
Fault/Events Summary Table
Table 1 is a Truth Table which describes the faults and events
that control the LM5027 drive outputs. For example the first
event is with UVLO being pulled below 0.4V, a possible remote shutdown condition. When this occurs the SS, and
SSSR capacitors are discharged, and the three drive outputs
will stop switching (outputs low). The last fault is if the OTP
pin is pulled low <1.25V, this would occur if an OTP protection
circuit is used, see Figure 7. In an OTP event, the LM5027
goes into a soft-stop shutdown.
15
www.national.com
LM5027
TABLE 1. Fault/Event Summary
Fault/Event
Vcc
UVLO
OTP
SS
SSSR
OUTA
OUTB
OUTSR
UVLO<0.4V
>6.2V
-
>1.25V
Fast
discharge
Fast
discharge
Low
Low
Low
2.0V<UVLO
>0.4V
>6.2V
-
>1.25V
Fast
discharge
after
SSSR<2V
Slow
discharge
Low
Low
Low
SS< 1V
>6.2V
>2.0V
>1.25V
-
Fast
discharge
Low
Low
Low
SSSR <2.0V
>6.2V
>2.0V
>1.25V
>4.0V
-
Switching
Switching
Low
OTP
<1.25V
>6.2V
>2.0V
-
Fast
discharge
after
SSSR<2V
Slow
discharge
Low
Low
Low
PWM Comparators
Feed-Forward Ramp
The pulse width modulator (PWM) comparator compares the
voltage ramp signal at the RAMP pin to the loop error signal.
The loop error signal is received from the external feedback
and isolation circuit in the form of a control current into the
matched pair of NPN transistors which sink current through a
5 kΩ resistor connected to the 5V reference. The resulting
control voltage is compared at the PWM input to a 1V level
shifted ramp signal. An opto-coupler detector can be connected directly between the REF pin and the COMP pin. Since
the COMP pin is a current mirror input, the potential difference
across the opto-coupler detector is nearly constant. The
bandwidth limiting phase delay which is normally introduced
by the significant capacitance of the opto-coupler is thereby
greatly reduced. Higher loop bandwidths can be realized
since the bandwidth-limiting pole associated with the optocoupler is now at a much higher frequency. The PWM comparator polarity is configured such that with no current into the
COMP pin, the controller produces maximum duty cycle at the
main gate drive output (OUTA).
An external resistor (RFF) and capacitor (CFF) connected to
VIN, AGND, and the RAMP pins is required to create the
PWM ramp signal as shown in Figure 8. The slope of the signal at the RAMP pin will vary in proportion to the input line
voltage. This varying slope provides line feed-forward information necessary to improve line transient response with
voltage mode control. The RAMP signal is compared to the
error signal by the pulse width modulator comparator to control the duty cycle of the outputs. With a constant error signal,
the on-time (tON) varies inversely with the input voltage (VIN)
to stabilize the volt-second product of the transformer primary. The power path gain of the conventional voltage-mode
pulse with modulator (oscillator generated ramp) varies directly with input voltage. The use of a line generated ramp
(input voltage feed-forward) nearly eliminates the gain variation. As a result, the feedback loop is only required to make
very small corrections for large changes in input voltage. At
the end of each clock period, an internal MOSFET with an
RDS(ON) of 10Ω (typical) is enabled to reset the CFF capacitor
voltage to ground.
www.national.com
16
LM5027
30099010
FIGURE 8. Feed-Forward Voltage Mode Configuration
Volt-Second Clamp
Oscillator and Sync Capability
An external resistor (RFF) and a capacitor (CFF) connected
between the VIN, RAMP and AGND pins is required to create
a saw-tooth modulation ramp signal as shown in Figure 8. The
slope of the RAMP will vary in proportion to the input line voltage. Varying the PWM ramp slope inversely with the input
voltage provides line feed-forward information necessary to
improve line transient response with voltage mode control.
With a constant error signal, the on time (tON) varies inversely
with the input voltage (VIN) to stabilize the volt-second product of the transformer primary.
The volt-second clamp compares the ramp signal (RAMP) to
a fixed 2.5V reference. By proper selection of RFF and CFF,
the maximum on-time of the main switch can be set to the
desired duration. An example will illustrate the use of the voltsecond clamp comparator to achieve a 90% duty cycle limit
at 200 kHz and 18V line input: A 90% duty cycle at 200 kHz
requires a 4.5 µs on-time. At 18V input the volt-second product is 81µs (18V x 4.5 µs). To achieve this clamp level:
The LM5027 oscillator frequency is set by the external resistor
connected between the RT pin and the ground (AGND). To
set a desired oscillator frequency, the necessary RT resistor
is calculated from:
For example, if the desired oscillator frequency is 200 kHz, a
27.4 kΩ resistor would be the nearest standard one percent
value. The RT resistor should be located as close as possible
to the IC and connected directly to the pins (RT and AGND).
The tolerance of the external resistor and the frequency tolerance indicated in the Electrical Characteristics must be
taken into account when determining the worst case operating frequency. The LM5027 can be synchronized to an external clock by applying a narrow pulse to the RT pin. The
external clock must be at least 10% higher than the free-running oscillator frequency set by the RT resistor. If the external
clock frequency is less than the RT resistor programming frequency, the LM5027 will ignore the synchronizing pulses. The
synchronization pulse should be coupled to the RT pin
through a 100 pF capacitor with a pulse width of 15 ns to 150
ns. When a synchronizing pulse transitions from low-to-high
(rising edge), the voltage at the RT pin must be driven to exceed 3.2V from its nominal 2.85V level. During the clock
signal low time, the voltage at the RT pin will be clamped at
2V by an internal regulator. The output impedance of the RT
regulator is approximately 100Ω. The RT resistor is always
required, whether the oscillator is free running or externally
synchronized.
RFF x CFF = VIN x tON / 2.5V
18V x 4.5 µs/ 2.5V = 32.4µ
Select CFF = 470 pF
RFF = 68.9 kΩ (closest standard value 68.1 kΩ)
The recommended capacitor value range for CFF is 100 pF
to 1000 pF. The CFF ramp capacitor is discharged at the conclusion of every cycle by an internal discharge switch controlled by either the PWM comparator, the CS comparator or
by the volt-second clamp comparator, which ever occurs first.
17
www.national.com
LM5027
Gate Drive Outputs
Thermal Protection
The LM5027 contains three unique gate drivers. OUTA, the
primary switch driver, is designed to drive the gate of an NChannel MOSFET and is capable of sourcing and sinking a
peak current of 2A. The active clamp drive, OUTB, is designed to drive a P-Channel MOSFET and is capable of
sourcing and sinking peak currents of 1A. The third driver,
OUTSR, is designed to drive the gate of a synchronous rectification MOSFET through a gate drive transformer. OUTSR
gate driver has a source and sink capability of 3A.
Internal Thermal Shutdown circuitry is provided to protect the
integrated circuit in the event the maximum rated junction
temperature is exceeded. When activated, typically at 165°C,
the controller is forced into a low power standby state with the
output drivers (OUTA, OUTB, and OUTSR), the bias regulators (VCC and REF) disabled. The thermal protection feature
is provided to prevent catastrophic failures from accidental
device overheating. During a restart, after thermal shutdown,
the soft-start capacitors (SS and SSSR) are fully discharged
and the controller follows a normal start-up sequence after the
junction temperature falls below the Thermal Shutdown hysteresis threshold (typically 145°C).
Driver Delay Timing
The three independent time delay adjustments allow a great
deal of flexibility for the user to optimize the efficiency of the
system. The active clamp output (OUTB) is in phase with the
main output (OUTA), with the active clamp output overlapping
the main output. The overlap time provides dead-time between the operation of the main switch and the P-Channel
active clamp switch at both the rising and falling edges. The
rising edge control is set by a resistor from the TIME1 pin to
the AGND pin. The falling edge control is set with a resistor
from the TIME3 pin to the AGND pin.
The rising edge of the PWM comparator output coincides with
the rising edge of OUTB and the falling edge of the OUTSR
output without delay, as shown in Figure 9. The rising edge
control for turning on the OUTSR output after the main output
(OUTA) has turned off is set with a resistor from the TIME2
pin to the AGND pin.
VIN
The voltage applied to the VIN pin, normally the same as the
system voltage applied to the power transformer’s primary
(VPWR), can vary in the range of the 13 to 90V with transient
capability of 105V. The current into VIN depends primarily on
the output driver capacitive loads, the switching frequency,
and any external loads on the VCC pin. If the power dissipation associated with the VIN current exceeds the package
capability, an external voltage should be applied to the VCC
pin (see Figure 10) to disable the internal start-up regulator.
The VCC regulation set point voltage is initially internally regulated to 9.5V. After the first OUTSR pulse, the VCC set point
voltage is reduced to 7.5V. If an external voltage is applied to
the VCC pin the required range is 8V to 15V . The VIN to VCC
series pass regulator includes a parasitic diode between VIN
and VCC. This diode should not be forward biased in normal
operation. The VCC voltage should never exceed the VIN
voltage. It is recommended the circuit of Figure 10 be used to
suppress transients which may occur at the input supply, in
particular where VIN is operated close to the maximum operating rating of the LM5027.
30099012
FIGURE 10. Start-up Regulator Power Reduction
30099011
FIGURE 9. LM5027 Driver Output Timing
www.national.com
18
For applications where the system input voltage (VPWR) exceeds 100V, VIN can be powered from an external start-up
regulator as shown in Figure 11. Connecting the VIN and VCC
pins together allows the LM5027 to be operated with VIN be-
30099014
FIGURE 11. Start-up Regulator for VPWR > 100V
Where VHYS is the desired UVLO hysteresis at VPWR, and
VPWR in the second equation is the turn-on voltage. For example, if the LM5027 is to be enabled when VPWR reaches
34V, and the hysteresis is 1.8V, then R1 is 90 kΩ and 5.6
kΩ. For this application R1 was selected to be 90.0 kΩ, R2
was selected to be 6.19 kΩ. The LM5027 can be remotely
shutdown by taking the UVLO pin below 0.4V with an external
open collector or open drain device, as shown in Figure 12.
The outputs and the VCC regulator are disabled in shutdown
mode.
UVLO
The under-voltage lockout threshold (UVLO) is internally set
to 2.0V at the UVLO pin. With two external resistors as shown
in Figure 12, the LM5027 is enabled when VPWR causes the
UVLO pin to exceed threshold voltage of 2V. When VPWR is
below the threshold, the internal 20 µA current sink is enabled
to reduce the voltage at the UVLO pin. When the UVLO pin
voltage exceeds the 2V threshold, the 20 µA current sink is
turned off causing the UVLO voltage to increase and providing hysteresis. The values of R1 and R2 can be determined
from the following equation:
R1 = VHYS/20 µA
19
www.national.com
LM5027
low 13V. To turn-off the internal start-up regulator the VCC
voltage must be raised above 9.9V. The voltage at the VCC
pin must not exceed 15V. The voltage source at the right side
of Figure 11 is typically derived from the power stage, and
becomes active when the LM5027 outputs are active.
For Applications > 100V
LM5027
30099016
FIGURE 12. UVLO Circuit with Shutdown Control
Oscillator
Voltage Feedback
The oscillator frequency is generally selected in conjunction
with the system magnetic components and any other aspects
of the system which may be affected by the frequency. The
RT resistor selection equation is specified in the Oscillator and
Sync Capability section. If the required frequency tolerance is
critical in particular application, the tolerance of the external
resistor and the frequency tolerance specified in the Electrical
Characteristics table must be considered when selecting the
RT resistor.
The COMP pin is designed to accept a current input typically
from an opto-coupler. A typical configuration is shown in Figure 13, where the emitter of the opto-coupler transistor is
connected to the COMP pin and the collector is connected to
the REF pin of the LM5027. When the output voltage is below
regulation, no current flows into the COMP pin and the
LM5027 operates at maximum duty cycle. At the secondary
side, VOUT is compared to a reference by the error amplifier
which has an appropriate frequency compensation network.
The amplifier output drives the opto-coupler, which in turn
drives the LM5027 COMP pin current mirror.
30099017
FIGURE 13. Typical COMP Configuration
www.national.com
20
The CS pin receives an input signal representative of the
transformer primary current, either from a current sense
transformer or from a resistor in series with the source of the
primary switch, as shown in Figure 14 and Figure 15. In both
cases the sensed current creates a ramping voltage across
RSENSE, and the RF/CF filter suppresses noise and leading
edge transients. The filtering components RSENSE, RF and
CF should be physically as close to the LM5027 as possible.
30099018
FIGURE 14. Transformer Current Sense
21
www.national.com
LM5027
The current sense components must be scaled for 0.5V at the
CS pin when an over-current condition exists.
If the voltage on the CS pin reaches 0.5V, the present cycle
will be immediately terminated. If the over-load event continues and the RES pin reaches 1V, the soft-start capacitor is
discharged and the LM5027 will go through an auto re-start
(Hiccup Mode). The Hiccup Mode time is set by the capacitor
on the RES pin.
Current Sense
LM5027
30099019
FIGURE 15. Resistor Current Sense
Soft-Start
Hiccup Mode Current Limit Restart
The capacitor on the SS pin determines the time required for
the output duty cycle to increase from zero to its final value
for regulation. The minimum acceptable time is dependent on
the output capacitance and the response of the feedback loop
that controls the COMP pin. If the soft-start time is too quick,
the output could significantly overshoot its intended voltage
before the feedback loop has a chance to regulate the PWM
controller. After power is applied and VCC has passed its upper UV threshold (9.5V), the voltage at the SS pin ramps up
as the external capacitor is charged with an internal 20 μA
current source. The voltage at the internal PWM comparator
input node follows the voltage at the SS pin. When the voltage
on the SS pin has reached 1.0V, PWM pulses appear at the
drive output with a very low duty cycle. The voltage at the SS
pin eventually increases to approximately 5.0V. The voltage
at the input to the PWM comparator and the PWM duty cycle
increase to the value required for regulation as determined by
the voltage regulation loop.
Hiccup mode operation is described in the Restart Time Delay
(Hiccup Mode) section. In the case of continuous current limit
detection at the CS pin, the time required to reach the 1.0V
RES pin threshold is:
For example, if CRES = 0.047 µF the time tCS in Figure 16 is
approximately 2.14 ms. After the voltage on the RES pin
reaches 1.0V, the 22 µA current source is turned-off and a 5
µA current source is turned-on. The Hiccup Mode time is:
where ΔV is 2.0V. With a CRES = 0.047 µF, the Hiccup Mode
time is 179 ms. After the Hiccup Mode off time is complete,
the RES pin voltage is pulled low and soft-start capacitor is
released allowing a soft-start sequence to commence.
The soft-start time trestart is set by the internal 22 µA current
source, and is equal to:
If CSS = 0.1 µF, trestart is = 6.41 ms
www.national.com
22
circuit. This off time results in lower average input current and
lower power dissipation within the power components.
30099023
FIGURE 16. Hiccup Mode Timing
Printed Circuit Board Layout
Application Circuit Example
The LM5027 Current Sense and PWM comparators are very
fast and respond to short duration noise pulses. The components at the CS, COMP, SS, UVLO, TIME1, TIME2, and
TIME3 pins should be physically close as possible to the IC,
thereby minimizing noise pickup on the PC board trace inductance. Layout consideration is critical for the current sense
filter. If a current sense transformer is used, both leads of the
transformer secondary should be routed to the sense filter
components and to the IC pins. The ground side of the transformer should be connected via a dedicated PC board trace
to the AGND pin, rather than through the ground plane.
If the current sense circuit employs a sense resistor in the
drive transistor source, low inductance resistors should be
used. In this case, all the noise sensitive, low-current ground
trace should be connected in common near the IC, and then
a single connection made to the power ground (sense resistor
ground point). The gate drive outputs of the LM5027 should
have short, direct paths to the power MOSFETs in order to
minimize inductance in the PC board. The two ground pins
(AGND, PGND) must be connected together with a short, direct connection, to avoid jitter due to relative ground bounce.
The following schematic shows an example of the LM5027
controlling a 100W active clamp forward power converter.
The input voltage range (VPWR) is 36V to 76V, and the output
voltage is 3.3V. The output current capability is 30 Amps.
Current sense transformer T3 provides information to the CS
pin for current limit protection. The error amplifier and reference U3 and U5 provide voltage feedback via opto-coupler
U2. Synchronous rectifiers Q3-Q6 minimize rectification losses in the secondary. An auxiliary winding on the power transformer T1 provides power to the LM5027 VCC pin when the
output is in regulation. The input UVLO levels are 34V for increasing VPWR, and approximately 32V for decreasing VPWR.
The circuit can be shutdown by forcing the ON/OFF input J2
below 0.4V. An external synchronizing frequency can be applied to the Oscillator input. The converter output current limit
is limited at 32A.
Special care was taken in this design such that the converter
will turn on with the output pre-biased without sinking current
from the output. More information is available in AN-1976.
23
www.national.com
LM5027
The hiccup mode provides the periodic cool-down time for the
power converter in the event of a sustained overload or short
30099039
LM5027
www.national.com
24
LM5027
Physical Dimensions inches (millimeters) unless otherwise noted
20 Lead eTSSOP
NS Package Number MXA20A
25
www.national.com
LM5027 Voltage Mode Active Clamp Controller
Notes
For more National Semiconductor product information and proven design tools, visit the following Web sites at:
Products
Design Support
Amplifiers
www.national.com/amplifiers
WEBENCH® Tools
www.national.com/webench
Audio
www.national.com/audio
App Notes
www.national.com/appnotes
Clock and Timing
www.national.com/timing
Reference Designs
www.national.com/refdesigns
Data Converters
www.national.com/adc
Samples
www.national.com/samples
Interface
www.national.com/interface
Eval Boards
www.national.com/evalboards
LVDS
www.national.com/lvds
Packaging
www.national.com/packaging
Power Management
www.national.com/power
Green Compliance
www.national.com/quality/green
Switching Regulators
www.national.com/switchers
Distributors
www.national.com/contacts
LDOs
www.national.com/ldo
Quality and Reliability
www.national.com/quality
LED Lighting
www.national.com/led
Feedback/Support
www.national.com/feedback
Voltage Reference
www.national.com/vref
Design Made Easy
www.national.com/easy
www.national.com/powerwise
Solutions
www.national.com/solutions
Mil/Aero
www.national.com/milaero
PowerWise® Solutions
Serial Digital Interface (SDI) www.national.com/sdi
Temperature Sensors
www.national.com/tempsensors SolarMagic™
www.national.com/solarmagic
Wireless (PLL/VCO)
www.national.com/wireless
www.national.com/training
PowerWise® Design
University
THE CONTENTS OF THIS DOCUMENT ARE PROVIDED IN CONNECTION WITH NATIONAL SEMICONDUCTOR CORPORATION
(“NATIONAL”) PRODUCTS. NATIONAL MAKES NO REPRESENTATIONS OR WARRANTIES WITH RESPECT TO THE ACCURACY
OR COMPLETENESS OF THE CONTENTS OF THIS PUBLICATION AND RESERVES THE RIGHT TO MAKE CHANGES TO
SPECIFICATIONS AND PRODUCT DESCRIPTIONS AT ANY TIME WITHOUT NOTICE. NO LICENSE, WHETHER EXPRESS,
IMPLIED, ARISING BY ESTOPPEL OR OTHERWISE, TO ANY INTELLECTUAL PROPERTY RIGHTS IS GRANTED BY THIS
DOCUMENT.
TESTING AND OTHER QUALITY CONTROLS ARE USED TO THE EXTENT NATIONAL DEEMS NECESSARY TO SUPPORT
NATIONAL’S PRODUCT WARRANTY. EXCEPT WHERE MANDATED BY GOVERNMENT REQUIREMENTS, TESTING OF ALL
PARAMETERS OF EACH PRODUCT IS NOT NECESSARILY PERFORMED. NATIONAL ASSUMES NO LIABILITY FOR
APPLICATIONS ASSISTANCE OR BUYER PRODUCT DESIGN. BUYERS ARE RESPONSIBLE FOR THEIR PRODUCTS AND
APPLICATIONS USING NATIONAL COMPONENTS. PRIOR TO USING OR DISTRIBUTING ANY PRODUCTS THAT INCLUDE
NATIONAL COMPONENTS, BUYERS SHOULD PROVIDE ADEQUATE DESIGN, TESTING AND OPERATING SAFEGUARDS.
EXCEPT AS PROVIDED IN NATIONAL’S TERMS AND CONDITIONS OF SALE FOR SUCH PRODUCTS, NATIONAL ASSUMES NO
LIABILITY WHATSOEVER, AND NATIONAL DISCLAIMS ANY EXPRESS OR IMPLIED WARRANTY RELATING TO THE SALE
AND/OR USE OF NATIONAL PRODUCTS INCLUDING LIABILITY OR WARRANTIES RELATING TO FITNESS FOR A PARTICULAR
PURPOSE, MERCHANTABILITY, OR INFRINGEMENT OF ANY PATENT, COPYRIGHT OR OTHER INTELLECTUAL PROPERTY
RIGHT.
LIFE SUPPORT POLICY
NATIONAL’S PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT DEVICES OR
SYSTEMS WITHOUT THE EXPRESS PRIOR WRITTEN APPROVAL OF THE CHIEF EXECUTIVE OFFICER AND GENERAL
COUNSEL OF NATIONAL SEMICONDUCTOR CORPORATION. As used herein:
Life support devices or systems are devices which (a) are intended for surgical implant into the body, or (b) support or sustain life and
whose failure to perform when properly used in accordance with instructions for use provided in the labeling can be reasonably expected
to result in a significant injury to the user. A critical component is any component in a life support device or system whose failure to perform
can be reasonably expected to cause the failure of the life support device or system or to affect its safety or effectiveness.
National Semiconductor and the National Semiconductor logo are registered trademarks of National Semiconductor Corporation. All other
brand or product names may be trademarks or registered trademarks of their respective holders.
Copyright© 2009 National Semiconductor Corporation
For the most current product information visit us at www.national.com
National Semiconductor
Americas Technical
Support Center
Email: [email protected]
Tel: 1-800-272-9959
www.national.com
National Semiconductor Europe
Technical Support Center
Email: [email protected]
National Semiconductor Asia
Pacific Technical Support Center
Email: [email protected]
National Semiconductor Japan
Technical Support Center
Email: [email protected]