NSC LM5026SD Active clamp current mode pwm controller Datasheet

LM5026
Active Clamp Current Mode PWM Controller
General Description
Features
The LM5026 PWM controller contains all of the features necessary to implement power converters utilizing the active
clamp / reset technique with current mode control. With the
active clamp technique, higher efficiencies and greater power
densities can be realized compared to conventional catch
winding or RDC clamp / reset techniques. Two control outputs
are provided, the main power switch control (OUT_A) and the
active clamp switch control (OUT_B). The device can be configured to control either a P-Channel or N-Channel clamp
switch. The main gate driver features a compound configuration, consisting of both MOS and Bipolar devices, providing
superior gate drive characteristics. The LM5026 can be configured to operate with bias voltages over a wide input range
of 8V to 100V. Additional features include programmable
maximum duty cycle, line under-voltage lockout, cycle-by-cycle current limit, hiccup mode fault operation with adjustable
timeout delay, PWM slope compensation, soft-start, 1MHz
capable oscillator with synchronization input / output capability, precision reference and thermal shutdown.
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Current Mode Control
Internal 100V Start-up Bias Regulator
3A Compound Main Gate Driver
High Bandwidth Opto-coupler Interface
Programmable Line Under-Voltage Lockout (UVLO) with
Adjustable Hysteresis
Versatile Dual Mode Over-Current Protection with hiccup
delay timer
Programmable Overlap or Deadtime between the Main
and Active Clamp Outputs
Programmable Maximum Duty Cycle Clamp
Programmable Soft-start
Leading Edge Blanking
Resistor Programmed 1MHz Capable Oscillator
Oscillator Sync I/O Capability
Precision 5V Reference
Packages
■ TSSOP-16
■ LLP-16 (5x5 mm) Thermally Enhanced
Typical Application Circuit
20147901
Simplified Forward Power Converter with Active Clamp Reset
© 2009 National Semiconductor Corporation
201479
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LM5026 Active Clamp Current Mode PWM Controller
January 15, 2009
LM5026
Connection Diagrams
20147950
16-Lead LLP
20147902
16-Lead TSSOP
Ordering Information
Order Number
Package Type
NSC Package Drawing
Supplied As
LM5026MT
TSSOP-16
MTC16
92 Units per anti-static tube
LM5026MTX
TSSOP-16
MTC16
2500 Units on Tape and Reel
LM5026SD
LLP-16
SDA16A
1000 Units on Tape and Reel
LM5026SDX
LLP-16
SDA16A
4500 Units on Tape and Reel
Pin Descriptions
PIN
NAME
1
VIN
2
UVLO
3
CS
4
5
DESCRIPTION
APPLICATION INFORMATION
Input Voltage Source
Input to the Start-up Regulator. Operating input range is 13V to 100V with
transient capability to 105V. For power sources outside of this range, the
LM5026 can be biased directly at VCC by an external regulator.
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. At the 1.25V threshold the SS pin is
released and the device enters the active mode.
Current Sense input for
current mode control and
current limit
If CS exceeds 0.5V the output pulse will be terminated, entering cycle-bycycle current limit. An internal switch holds CS low for 100nS after OUT_A
switches high to blank leading edge transients.
RES
Restart Timer
If cycle-by-cycle current limit is reached during any cycle, a 10uA current
is sourced to the RES pin capacitor. If the RES capacitor voltage reaches
2.5V, the soft-start capacitor will be fully discharged and then released with
a pull-up current of 1uA. After the first output pulse at OUT_A (when SS
=1.4V), the SS pin charging current will revert back to 50 µA.
TIME
Gate Drive Overlap or
Deadtime Control
An external resistor (RSET) sets either the overlap time or deadtime for the
active clamp output. An RSET resistor connected between TIME and
AGND produces in-phase OUT_A and OUT_B pulses with overlap. An
RSET resistor connected between TIME and REF produces out-of-phase
OUT_A and OUT_B pulses with deadtime.
6
REF
Output of 5V Reference
Maximum output current is 10mA. Locally decouple with a 0.1µF capacitor.
7
VCC
Output of the high voltage
If an auxiliary winding raises the voltage on this pin above the regulation
start-up regulator. The VCC setpoint, the internal start-up regulator will shutdown, thus reducing the IC
voltage is regulated to 7.6 V. power dissipation.
8
OUT_A
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Main Output Driver
Output of the main switch PWM gate driver. Capable of 3A peak sink
current.
2
NAME
9
OUT_B
Active Clamp Output Driver
Output of the active clamp switch gate driver. Capable of 0.5A peak source
and sink current.
10
PGND
Power Ground
Connect directly to Analog Ground
11
AGND
Analog Return
Connect directly to Power Ground.
12
SS
Soft-start
An external capacitor and an internal 50 µA current source set the soft-start
ramp. The SS current source is reduced to 1 µA following a restart event.
The soft-stop discharge current is 50 µA.
13
COMP
Input to the Pulse Width
Modulator
The external opto-coupler connected to the COMP pin sources current into
an internal NPN current mirror. The PWM duty cycle is maximum 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.
14
RT
15
SYNC
16
DCL
EP
DESCRIPTION
APPLICATION INFORMATION
Oscillator Frequency Control Normally biased at 2V. The total external resistance connected between
RT and AGND sets the internal oscillator frequency.
Oscillator Synchronization
Input/Output
The internal oscillator can be synchronized to an external clock with an
external pull-down device. Multiple LM5026 devices can be synchronized
together by connection of their SYNC pins.
Maximum Duty Cycle Control An external resistor divider connected from RT to AGND sets the maximum
output duty cycle for OUT_A.
Exposed Pad Exposed Pad, underside of
(LLP
LLP package
Package
Only)
Connect to system ground plane for reduced thermal resistance.
3
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LM5026
PIN
LM5026
Block Diagram
20147912
FIGURE 1. Simplified Block Diagram
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4
VIN to GND
VCC to GND
CS to GND
COMP Input Current
All other inputs to GND
VIN Voltage
External Voltage Applied to VCC
Operating Junction Temperature
-0.3V to 105V
-0.3V to 16V
-0.3 to 1.0V
10mA
-0.3 to 7V
Operating Ratings
LM5026
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
ESD Rating (Note 2)
Human Body Model
Storage Temperature Range
Junction Temperature
Absolute Maximum Ratings (Note 1)
2kV
-65°C to 150°C
150°C
(Note 1)
13 to 100V
8V to 15V
-40°C to +125°C
Electrical Characteristics
Specifications with standard typeface are for TJ = 25°C, and those with boldface type apply over full Operating Junction Temperature range. VIN = 48V, VCC = 10V, RT = 30.0kΩ, RSET = 34.8kΩ) unless otherwise stated (Note 3)
Symbol
Parameter
Conditions
Min
Typ
Max
7.9
Units
Startup Regulator
VCC Reg
I-VIN
VCC Regulation
No Load
7.3
7.6
VCC Current Limit
(Note 4)
20
25
V
Startup Regulator
Leakage (external Vcc
Supply)
VIN = 100V
165
500
µA
Shutdown Current (Iin) UVLO = 0V
350
450
µA
mA
VCC Supply
VCC Under-voltage
Lockout Voltage
(positive going Vcc)
VCC Reg 220mV
VCC Reg 120mV
VCC Under-voltage
Hysteresis
1.0
1.5
VCC Supply Current
(ICC)
V
2.0
V
4.2
mA
5
5.15
V
25
50
mV
Cgate = 0, UVLO = 1.3V
Reference Supply
VREF
Ref Voltage
IREF = 0 mA
4.85
Ref Voltage Regulation IREF = 0 to 10mA
Ref Current Limit
10
20
0.3
0.4
mA
UVLO Shutdown/Standby
Undervoltage
Shutdown Threshold
Undervoltage
Shutdown Hysteresis
0.5
0.1
V
V
Undervoltage Standby
Threshold
1.21
1.25
1.29
V
Undervoltage Standby
Hysteresis Current
Source
16
20
24
µA
0.45
0.5
0.55
V
Current Limit
Cycle by Cycle
Threshold Voltage
ILIM Delay to Output
CS step from 0 to 0.6V Time to
onset of OUT transition (90%)
Cgate=0
Leading Edge Blanking
Time
CS Sink Impedance
(clocked)
40
70
ICS = 10mA
5
ns
100
130
ns
30
50
Ω
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LM5026
Symbol
Parameter
Conditions
Min
Typ
Max
Units
Restart Threshold
2.4
2.55
2.7
V
Fault Charging Current
7.5
10
12.5
µA
Discharging Current
7.5
10
12.5
µA
Soft-start Current
Source
38
50
58
Soft-stop Current Sink
38
50
58
Soft-start Current
Source following a
restart event
0.6
1
1.3
Over Current Restart
Soft-Start
µA
Oscillator
Frequency1
RT = 30.0 kΩ
180
200
220
kHz
Frequency2
RT = 10.0 kΩ
520
590
660
kHz
SYNC Source Current
200
µA
SYNC Sink Impedance Can sync up to 5 like controllers
minimum
100
Ω
Sync Threshold (falling)
1.4
Sync Pulse Width
Minimum
V
ns
15
PWM Comparator
Delay to Output
CS stepped, Time to onset of
OUT_A transition low
40
Mimimum Duty Cycle
ICOMP = 1mA
Maximum Duty Cycle
Limit 1
UVLO=1.3V, COMP = open,
VDCL = 2.5V
80
%
Maximum Duty Cycle
Limit 2
UVLO=1.3V, COMP = open,
VDCL = VRT x 0.875
70
%
Maximum Duty Cycle
Limit 3
UVLO=2.92V, COMP = open,
VDCL = 2.5V
40
%
1.4
V
1700
Ω
0
SS to PWM Offset
COMP Input
Impedance
Small signal impedance
Slope Compensation
Amplitude
Delta increase at PWM
comparator to CS
ns
%
90
115
mV
OUT_A High Saturation MOS Device @ Iout = -10mA,
5
10
OUTPUT_A Peak
Current Sink
3
Ω
A
9
Ω
ns
75
Output Section
Bipolar Device @ Vcc/2
OUT_A Low Saturation MOS Device @ Iout = 10mA,
6
OUTPUT_A Rise Time Cgate = 2.2nF
20
OUTPUT_A Fall Time
Cgate = 2.2nF
15
OUT_B High Saturation Iout = -10mA,
10
20
Ω
OUT_B Low Saturation Iout = 10mA,
10
20
OUTPUT_B Rise Time Cgate = 470pF
15
Ω
ns
OUTPUT_B Fall Time
15
ns
Cgate = 470pF
ns
Output Timing Control
Overlap Time
RSET = 34.8 kΩ connected to
GND, 50% to 50% transitions
70
100
130
ns
Deadtime
RSET = 30.0 kΩ connected to
REF, 50% to 50% transitions
70
100
130
ns
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Parameter
Conditions
Min
Typ
Max
Units
150
165
°C
25
°C
MTC Package
125
°C/W
SDA Package
32
°C/W
Thermal Shutdown
TSD
Thermal Shutdown
Temp.
Thermal Shutdown
Hysteresis
Thermal Resistance
θJA
Junction to Ambient
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: The human body model is a 100 pF capacitor discharged through a 1.5 kΩ resistor into each pin.
Note 3: Min and Max limits are 100% production tested at 25 ºC. Limits over the operating temperature range are guaranteed through correlation using Statistical
Quality Control (SQC) methods. Limits are used to calculate National’s Average Outgoing Quality Level (AOQL).
Note 4: Device thermal limitations may limit usable range.
Typical Performance Characteristics
VCC Regulator Start-up Characteristics, VCC vs Vin
VCC vs ICC
20147904
20147903
VREF vs IREF
Soft-start, Soft-stop and Restart Current vs Temperature
20147938
20147905
7
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LM5026
Symbol
LM5026
Oscillator Frequency vs RT
Oscillator Frequency vs Temperature
20147907
20147906
Overlap Time vs RSET
Overlap Time vs Temperature
20147908
20147909
Deadtime vs RSET
Deadtime vs Temperature
20147910
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20147911
8
LM5026
Max Duty Cycle vs UVLO
Max Duty Cycle vs DCL
20147935
20147936
COMP Current vs INV PWM Comparator Voltage
20147937
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LM5026
Detailed Operating Description
Line Under-Voltage Detector
The LM5026 PWM controller contains all of the features necessary to implement power converters utilizing the active
clamp reset technique with current mode control. With the
active clamp reset, higher efficiencies and greater power densities can be realized compared to conventional catch winding
or RDC clamp reset techniques. The LM5026 provides two
control outputs, the main power switch control (OUT_A) and
the active clamp switch control (OUT_B). The device can be
configured to drive either a P-Channel or N-Channel clamp
switch. The main switch gate driver features a compound
configuration consisting of both MOS and bipolar devices,
which provide superior gate drive characteristics. The
LM5026 can be configured to operate with bias voltages over
a wide input range from 8V to 100V. Additional features include programmable maximum duty cycle, line under-voltage
lockout, cycle-by-cycle current limit, hiccup mode fault protection with adjustable delays, PWM slope compensation,
soft-start, a 1MHz capable oscillator with synchronization Input / Output capability, precision reference and thermal shutdown.
The LM5026 contains a dual level Under-Voltage Lockout
(UVLO) circuit. When the UVLO pin voltage is below 0.4V the
controller is in a low current shutdown mode. When the UVLO
pin voltage is greater than 0.4V but less than 1.25V, the controller is in standby mode. In standby mode the VCC and REF
bias regulators are active while the controller outputs are disabled. When the VCC and REF outputs exceed the VCC and
REF under-voltage thresholds and the UVLO pin voltage is
greater than 1.25V, the outputs are enabled and normal operation begins. An external set-point voltage divider from VIN
to GND can be used to set the operational range of the converter. The divider must be designed such that the voltage at
the UVLO pin will be greater than 1.25V when VIN is in the
desired operating range. UVLO hysteresis is accomplished
with an internal 20uA current source that is switched on or off
into the impedance of the set-point divider. When the UVLO
threshold is exceeded, the current source is activated to instantly raise the voltage at the UVLO pin. When the UVLO pin
voltage falls below the 1.25V threshold, the current source is
turned off causing the voltage at the UVLO pin to fall. The
hysteresis of the 0.4V shutdown comparator is fixed at
100mV.
The UVLO pin can also be used to implement various remote
enable / disable functions. Pulling the UVLO pin below the
0.4V threshold totally disables the controller. Pulling the UVLO pin to a potential between 1.25 and 0.4V places the
controller in standby with the VCC and REF regulators operating. Turning off a converter by forcing the UVLO pin to the
standby condition provides a controlled soft-stop. The controller outputs are not directly disabled in standby mode,
rather the soft-start capacitor is discharged with a 50µA sink
current. Discharging the soft-start capacitor gradually reduces the PWM duty cycle to zero, providing a slow controlled
discharge of the power converter output filter. This controlled
discharge can help prevent uncontrolled behavior of self-driven synchronous rectifiers during turn-off.
High Voltage Start-Up Regulator
The LM5026 contains an internal high voltage start-up regulator that allows the input pin (VIN) to be connected directly
to a nominal 48V dc line voltage. The regulator output (VCC)
is internally current limited to 20mA. When power is applied
and the UVLO pin potential is greater than 0.4V, the regulator
is enabled and sources current into an external capacitor
connected to the VCC pin. The recommended capacitance
range for the VCC regulator is 0.1µF to 100µF. The VCC regulator provides power to the internal voltage reference, PWM
controller and gate drivers. The controller outputs are enabled
when the voltage on the VCC pin reaches the regulation point
of 7.6V, the internal voltage reference (REF) reaches its regulation point of 5V and the UVLO voltage is greater than
1.25V. In typical applications, an auxiliary transformer winding is connected through a diode to the VCC pin. This winding
must raise the VCC voltage above 8V to shut off the internal
start-up regulator. Powering VCC from an auxiliary winding
improves efficiency while reducing the controller’s power dissipation.
The external VCC capacitor must be sized such that the current delivered from the capacitor and the VCC regulator will
maintain a VCC voltage greater than 6.2V during the initial
start-up. During a fault mode when the converter auxiliary
winding is inactive, external current draw on the VCC line
should be limited such that the power dissipated in the startup regulator does not exceed the maximum power dissipation
of the IC package. An external start-up or bias regulator can
be used to power the LM5026 instead of the internal start-up
regulator by connecting the VCC and the VIN pins together
and connecting an external bias supply to these two pins.
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PWM Outputs
The relative phase of the main switch gate driver OUT_A and
active clamp gate driver OUT_B can be configured for multiple applications. For active clamp configurations utilizing a
ground referenced P-Channel clamp switch, the two outputs
should be in phase, with the active clamp output overlapping
the main output. For active clamp configurations utilizing a
high side N-Channel switch, the active clamp output should
be out of phase with main output and there should be a dead
time between the two gate drive pulses. A distinguishing feature of the LM5026 is the ability to accurately configure either
deadtime (both off) or overlap time (both on) of the gate driver
outputs. The overlap / deadtime magnitude is controlled by
the resistor value (RSET) connected to the TIME pin of the
controller. The opposite end of the resistor can be connected
to either REF for deadtime control or to AGND for overlap
control. The internal configuration detector senses the direction of current flow in the TIME pin resistor and configures the
phase relationship of the main and active clamp outputs.
10
LM5026
20147913
FIGURE 2. PWM Output Phasing / Timing
The rising edge overlap or deadtime and the falling edge
overlap or deadtime are identical and are independent of operating frequency or duty cycle. The magnitude of the overlap/
deadtime can be calculated as follows:
Overlap Time = 2.8 x RSET + 2
Deadtime = 2.9 x RSET + 14
With RSET in K Ohms and overlap / deadtime in nanoseconds
PWM Comparator/Slope
Compensation
The PWM comparator modulates the pulse width of the controller output by comparing the current sense ramp signal to
the loop error signal. This comparator is optimized for speed
in order to achieve minimum controllable duty cycles. The
loop error signal is input into the controller in the form of a
control current into the COMP pin. The COMP pin control
current is internally mirrored by a matched pair of NPN transistors which sink current through a 5 kΩ resistor connected
to the 5V reference. The resulting error signal passes through
a 1.4V level shift and a gain reducing 3:1 resistor divider before being applied to the pulse width modulator.
The opto-coupler detector can be connected between the
REF pin and the COMP pin. Because the COMP pin is controlled by a current input, the potential difference across the
optocoupler detector is nearly constant. The bandwidth limiting phase delay which is normally introduced by the significant capacitance of the opto-coupler is greatly reduced.
Greater system loop bandwidth can be realized, since the
bandwidth-limiting pole associated with the opto-coupler 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 the maximum duty cycle at the
main gate driver output.
Gate Driver Outputs
The LM5026 provides two gate driver outputs, the main power
switch control (OUT_A) and the active clamp switch control
(OUT_B). The main gate driver features a compound configuration, consisting of both MOS and bipolar devices, which
provide superior gate drive characteristics. The bipolar device
provides most of the drive current capability and sinks a relatively constant current, which is ideal for driving large power
MOSFETs. As the switching event nears conclusion and the
bipolar device saturates, the internal MOS device provides a
low impedance to compete the switching event.
During turn-off at the Miller plateau region, typically between
2V - 4V, the voltage differential between the output and PGND
is small and the current source characteristic of the bipolar
device is beneficial to reduce the transition time. During turnon, the resistive characteristics of a purely MOS gate driver
is adequate since the supply to output voltage differential is
fairly large in the Miller region.
20147914
FIGURE 3. Compound Gate Driver
11
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LM5026
20147915
FIGURE 4. Opto-coupler to LM5026 COMP Interface
For duty cycles greater than 50 percent, current mode control
circuits are subject to sub-harmonic oscillation. By adding an
additional fixed slope voltage ramp signal (slope compensation) to the current sense signal, this oscillation can be avoided. The LM5026 integrates this slope compensation by
summing a current ramp generated by the oscillator with the
current sense signal. The PWM comparator ramp signal is a
combination of the current waveform at the CS pin, and an
internally generated slope compensation ramp derived from
the oscillator. The internal ramp has an amplitude of 0 to 45
µA which is sourced into an internal 2 kΩ resistor, plus the
external impedance at the CS pin. Additional slope compensation may be added by increasing the source impedance of
the current sense signal.
20147916
Maximum Duty Cycle Clamp
FIGURE 5. Programming oscillator Frequency and
Maximum Duty Cycle Clamp
Controlling the maximum duty cycle of an active clamp reset
PWM controller is necessary to limit the voltage stress on the
main and active clamp MOSFETs. The relationship between
the maximum drain-source voltage of the MOSFETs and the
maximum PWM duty cycle is provided by the following equation:
Line Voltage Duty Cycle Limiter - The maximum duty cycle for
the main output driver is also limited by the voltage at the UVLO pin, which is normally proportional to VIN. The controller
outputs are disabled until the UVLO pin voltage exceeds
1.25V. At the minimum operating voltage (when UVLO =
1.25V) the maximum duty cycle starts at the duty cycle clamp
level programmed by the DCL pin voltage (80% or less). As
the line voltage increases, the maximum duty cycle decreases linearly with increasing UVLO voltage, as illustrated in
Figure 6. Ultimately the duty cycle of the main output is controlled to the least of the following three variables: the duty
cycle controlled by the PWM comparator, the programmable
maximum duty cycle clamp, or the line voltage dependent
duty cycle limiter.
The main output (OUT_A) duty cycle is normally controlled by
the control current sourced into the COMP pin from the external feedback circuit. When the feedback demands maximum output from the converter, the duty cycle will be limited
by one of two circuits within the LM5026: the user programmable duty cycle clamp and the voltage-dependent duty
cycle limiter, which varies inversely with the input line voltage.
Programmable Duty Cycle Clamp – The maximum allowed
duty cycle can be programmed by setting a voltage at the DCL
pin to a value less than 2V. The recommended method to set
the DCL pin voltage is with a resistor divider connected from
the RT pin to AGND. The voltage at the RT pin is internally
regulated to 2V, while the current sourced from the RT pin
sets the oscillator frequency. The maximum duty can be programmed, according to the following equation:
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Overload Protection Timer
The LM5026 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 means of an external capacitor at
the RES pin. During each PWM cycle the LM5026 either
sources or sinks current from the RES pin capacitor. If no
current limit is detected during a cycle, a 10uA discharge current sink is enabled to hold the RES pin at ground. If a current
limit is detected, the 10uA sink current is disabled and a 10
uA current source causes the voltage at RES pin to gradually
increase. In the event of an extended overload condition, the
LM5026 protects the converter with cycle-by-cycle current
limiting while the voltage at RES pin increases. If the RES
voltage reaches the 2.5V threshold, the following restart sequence occurs (see Figure 7):
• The RES capacitor and SS capacitors are fully discharged.
• The soft-start current source is reduced from 50 µA to 1
µA
• The SS capacitor voltage slowly increases. When the SS
voltage reaches 1.4V, the PWM comparator will produce
the first output pulse. After the first pulse occurs, the SS
source current reverts to the normal 50 µA level. The SS
voltage increases at its normal rate gradually increasing
the duty cycle of the output drivers
• If the overload condition persists after restart, cycle-bycycle current limiting will cause the voltage on the RES
capacitor to increase 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 10 µA current sink
and normal operation resumes.
The overload timer function is very versatile and can be configured for the following modes of protection:
1. Cycle-by-cycle only: The hiccup mode can be
completely disabled by connecting the RES pin to AGND.
In this configuration, the cycle-by-cycle protection will
limit the output current indefinitely and no hiccup
sequences will occur.
2. Hiccup only: The timer can be configured for immediate
activation of a hiccup sequence upon detection of an
overload by leaving the RES pin open circuit.
3. Delayed Hiccup: The most common configuration as
previously described, is a programmed interval of cycleby-cycle limiting before initiating a hiccup mode restart.
The advantage of this configuration is short term
overload conditions will not cause a hiccup mode restart,
however during extended overload conditions the
average dissipation of the power converter will be very
low.
4. Externally Controlled Hiccup: The RES pin can also
be used as an input. By externally driving the pin to a level
greater than the 2.5V hiccup threshold, the controller will
be forced into the delayed restart sequence. If the RES
20147917
FIGURE 6. Maximum Duty Cycle vs UVLO Voltage
Soft-Start/Soft-Stop
The soft-start circuit allows the regulator to gradually reach a
steady state operating point, thereby reducing start-up stresses and current surges. Upon turn-on, the SS pin capacitor is
discharged by an internal switch. When the UVLO, VCC and
REF pins reach their operating thresholds, the SS capacitor
is released and charged with a 50uA current source. The
PWM comparator control voltage is clamped to the SS pin
voltage. When the PWM input reaches 1.4V, output pulses
commence with slowly increasing duty cycle. The voltage at
the SS pin eventually increases to 5V, while the voltage at the
PWM comparator increases to the value required for regulation determined by the voltage feedback loop.
If the UVLO pin voltage falls below the 1.25V standby threshold but above the 0.4V shutdown threshold, the 50uA SS pin
source current is disabled and a 50uA sink current discharges
the soft-start capacitor. As the SS voltage falls and clamps
the PWM comparator input, the PWM duty cycle will gradually
fall to zero. This soft-stop feature produces a gradual reduction of the power converter output voltage. This gradual discharge of the output filter prevents oscillations in the selfdriven synchronous rectifiers on the secondary side of the
converter during turn-off.
Current Sense/Current Limit
The CS input provides a control ramp for the pulse width
modulator and current limit detection for overload protection.
If the sensed voltage at the CS comparator exceeds 0.5V the
present cycle is terminated (cycle-by-cycle current limit
mode).
A small RC filter, located near the controller, is recommended
for the CS input pin. An internal FET connected to the CS
input discharges the current sense filter capacitor at the conclusion of every cycle to improve dynamic performance. This
same FET remains on for an additional 100nS at the start of
each main switch cycle to attenuate the leading edge spike in
the current sense signal.
The CS 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 pins of the LM5026 (CS
and AGND pins). If a current sense transformer is used, both
13
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LM5026
leads of the transformer secondary should be routed to the
filter network, which should be located close to the IC. If a
sense resistor located in the source of the main switch MOSFET is used for current sensing, a low inductance type of
resistor is required. 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).
LM5026
pin is used as an input, the driving source should be
current limited to less than 5 mA. For example, the
external trigger for a delayed restart sequence could
come an over-temperature protection circuit.
20147918
FIGURE 7. Hiccup Over-Load Restart Timing
Oscillator and Sync Capability
The LM5026 oscillator frequency is set by the external resistance connected between the RT pin and ground (AGND). To
set a desired oscillator frequency (F) the necessary value of
total RT resistance can be calculated from:
The RT resistor(s) should be located very close to the device
and connected directly to the pins of the IC (RT and AGND).
The SYNC pin can be used to synchronize the internal oscillator to an external clock. An open drain output is the recommended interface between the external clock to the LM5026
SYNC pin as illustrated in Figure 8. The clock pulse width
must be greater than 15 ns. The external clock frequency
must be a higher than the free running frequency set by the
RT resistance.
20147920
FIGURE 9. Sync from Multiple Devices
Multiple LM5026 devices can be synchronized together simply by connecting the devices SYNC pins together as shown
in Figure 9. Care should be taken to ensure the ground potential differences between devices are minimized. In this
configuration all of the devices will be synchronized to the
highest frequency device. The internal block diagram of the
oscillator and synchronization circuit is shown in Figure 10.
The SYNC I/O pin is a CMOS buffer with pull-up current limited to 200 µA. If an external device forces the SYNC pin low
before the internal oscillator ramp completes its charging cycle, the ramp will be reset and another cycle begins. If the
SYNC pins of multiple LM5026 devices are connected together, the first SYNC pin that pulls low will reset the oscillator
RAMP of all other devices. All controllers will operate in phase
when synchronized using the SYNC I/O feature. Up to five
LM5026 devices can be synchronized using this technique.
20147919
FIGURE 8. Sync from External Clock
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LM5026
20147922
FIGURE 11. Input Transient Protection
FOR APPLICATION > 100V
For applications where the system input voltage exceed 100V
or IC power dissipation is a concern, the LM5026 can be
powered from an external start-up regulator as shown in Figure 12. In this configuration, the VIN and the VCC pins should
be connected together, which allows the LM5026 to be operated below 13V. The voltage at the VCC pin must be greater
than 8V yet not exceed 15V. An auxiliary winding can be used
to reduce the dissipation in the external regulator once the
power converter is active.
20147921
FIGURE 10. Oscillator Sync I/O Block Diagram
Thermal Protection
Internal Thermal Shutdown circuitry is provided to protect the
integrated circuit in the event the maximum junction temperature is exceeded. When activated, typically at 165°C, the
controller is forced into a low power standby state with the
output drivers and the bias regulator disabled. The device will
restart after the thermal hysteresis (typically 25°C). During
thermal shutdown, the soft-start capacitor is fully discharged
and the controller follows a normal start-up sequence after the
junction temperature falls to the operating level.
20147923
Applications Information
FIGURE 12. Start-up Regulator for VPWR >100V
LINE INPUT (VIN)
The LM5026 contains an internal high voltage start-up regulator that allows the input pin (VIN) to be connected directly
to a nominal 48V line voltage. The voltage applied to the VIN
pin can vary in the range of 13 to 100V with transient capability
to 105V. When power is applied and the UVLO pin potential
is greater than 0.4V, the VCC regulator is enabled and
sources current into an external capacitor connected to the
VCC pin. When the voltage on the VCC pin reaches the regulation point of 7.7V, the internal voltage reference (REF) is
enabled. The reference regulation set point is 5V. The controller outputs are enabled when the UVLO pin potential is
greater than 1.25V. In typical applications, an auxiliary transformer winding is connected through a diode to the VCC pin.
This winding must raise the VCC voltage above 8V to shut off
the internal start-up regulator. It is recommended a filtering
circuit shown in Figure 11 be used to suppress transients,
which may occur at the input supply, in particular when VIN
is operated close to the maximum operating rating.
UNDER-VOLTAGE LOCKOUT (UVLO)
When the UVLO pin voltage is below 0.4V the controller is in
a low current shutdown mode. When the UVLO pin voltage is
greater than 0.4V but less than 1.25V the controller is in
standby mode. When the UVLO pin voltage is greater than
1.25V the controller is fully enabled. Typically, two external
resistors program the minimum operational voltage for the
power converter as shown in Figure 13. When UVLO pin voltage is above the 1.25V threshold, an internal 20 μA current
source is enabled to raise the voltage at the UVLO pin, thus
providing threshold hysteresis. Resistance values for R1 and
R2 can be determined from:
R1 = VHYS / 20 µA
Where VPWR is the desired turn-on voltage and VHYS is the
desired UVLO hysteresis at VPWR. For example, if the LM5026
is to be enabled when VPWR reaches 33V, and disabled when
VPWR is decreased to 30V, R1 calculates to 150 kΩ, and R2
calculates to 5.9 kΩ. The voltage at the UVLO pin should not
exceed 6V at any time. Be sure to check both the power and
voltage rating for the selected R1 resistor.
15
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LM5026
The SYNC pin can be used to synchronize the internal oscillator to an external clock. An open drain output is the recommended interface from the external clock to the SYNC pin.
The clock pulse width should be greater than 15 ns. The external clock must be a higher frequency than the free running
frequency set by the RT resistor. Multiple LM5026 devices
can be synchronized together simply by connecting the devices SYNC pins together. Care should be taken to ensure
the ground potential differences between devices are minimized. In this configuration all of the devices will be synchronized to the highest frequency device.
20147924
VOLTAGE FEEDBACK (COMP)
The COMP pin is designed to accept the voltage loop feedback error signal from the regulated output via an error amplifier and (typically) an optocoupler. In a typical configuration,
VOUT is compared to a precision reference voltage by the
error amplifier. The amplifier’s output drives the optocoupler,
which in turn drives the COMP pin. The parasitic capacitance
of the optocoupler often limits the achievable loop bandwidth
for a given power converter. The optocoupler LED and detector junction capacitance produce a low frequency pole in
the voltage regulation loop. The LM5026 current controlled
optocoupler interface (COMP) previously described, greatly
increases the pole frequency associated with the optocoupler.
FIGURE 13. Basic UVLO Configuration
Remote configuration of the controller’s operational modes
can be accomplished with open drain device(s) connected to
the UVLO pin as shown in Figure 14.
CURRENT SENSE (CS)
The CS pin receives an input signal representative of the
transformer primary current, either from a current sense
transformer (Figure 15) or from a resistor in series with the
source of the primary switch (Figure 16). In both cases the
sensed current creates a ramping voltage across R1, while
the RF/CF filter suppresses noise and transients. R1, RF and
CF should be as physically close to the LM5026 as possible,
and the ground connection from the current sense transformer, or R1, should be a dedicated track to the AGND pin.
The current sense components must provide >0.5V at the CS
pin when an over-current condition exists.
20147925
FIGURE 14. Remote Standby and Disable Control
OSCILLATOR (RT, SYNC)
Oscillator (RT, SYNC) The oscillator frequency is generally
selected in conjunction with the design of the system magnetic components along with the volume and efficiency goals
for a given power converter design. The total RT resistance
at the RT pin sets the oscillator frequency. The RT resistors
should be one of the first components placed and connected
when designing the PC board. Direct, short connections to
each side of the RT resistors (RT, DCL and AGND pins) are
recommended .
20147926
FIGURE 15. Current Sense Using a Current Sense Transformer
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LM5026
20147927
FIGURE 16. Current Sense Using a Source Sense Resistor (R1)
HICCUP MODE CURRENT LIMIT RESTART (RES)
The basic operation of the hiccup mode current limit restart is
described in the functional description. The delay time to
restart is programmed with the selection of the RES pin capacitor CRES as illustrated in Figure 7. In the case of continuous cycle-by-cycle current limit detection at the CS pin, the
time required for CRES to reach the 2.5V hiccup mode threshold is:
SOFT-START (SS)
An internal current source and an external soft-start capacitor
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. If the soft-start time is too
quick, the output could overshoot its intended voltage before
the feedback loop can regulate the PWM controller. After
power is applied and the controller is fully enabled, the voltage
at the SS pin ramps up as CSS is charged by an internal 50
µA current source. The voltage at the output of the COMP pin
current mirror is clamped to the same potential as the SS pin
by a voltage buffer with a sink-only output stage. When the
SS voltage reaches ≈1.4V, PWM pulses appear at the driver
output with very low duty cycle. The PWM duty cycle gradually
increases as the voltage at the SS pin charges to ≈5.0V.
For example, if CRES = 0.01 µF the time t1 is approximately
2.5 ms.
The cool down time, t2 is set by the soft-start capacitor (CSS)
and the internal 1 µA SS current source, and is equal to:
VOLTAGE DEPENDENT MAXIMUM DUTY CYCLE
As the input source VPWR increases the voltage at the UVLO
pin increases proportionately. To limit the Volt x Seconds applied to the transformer, the maximum allowed PWM duty
cycle decreases as the UVLO voltage increases. If it is desired to increase the slope of the voltage limited duty cycle
characteristic, two possible configurations are shown in Figure 17. After the LM5026 is enabled, the zener diode causes
the UVLO pin voltage to increase more rapidly with increasing
input voltage (V PWR). The voltage dependent maximum duty
cycle clamp varies with the UVLO pin voltage according to the
following equation:
If CSS = 0.01 µF, t2 is ≈14 ms.
The soft-start time t3 is set by the internal 50 µA current
source, and is equal to:
Voltage-Dependent Duty Cycle (%) = 107 - 21.8 X UVLO
The time t2 provides a periodic cool-down time for the power
converter in the event of a sustained overload or short circuit.
This results in lower average input current and lower power
dissipated within the power components. It is recommended
that the ratio of t2/(t1 + t3) be in the range of 5 to 10 to make
good use of this feature. If the application requires no delay
from the first detection of a current limit condition to the onset
of the hiccup mode (t1 = 0), the RES pin can be left open (no
external capacitor). If it is desired to disable the hiccup mode
current limit operation, the RES pin should be connected to
ground (AGND).
17
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LM5026
duty cycle. As the UVLO pin voltage increases from 1.25V,
the maximum duty cycle is reduced by the voltage dependent
duty cycle limiter previously as described and illustrated in
Figure 6.
Printed Circuit Board Layout
The LM5026 Current Sense and PWM comparators are very
fast, and respond to short duration noise pulses. The components at the CS, COMP, SS, DCL, UVLO, TIME, SYNC and
the RT pins should be as physically close as possible to the
IC, thereby minimizing noise pickup on the PC board tracks.
Layout considerations are 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 each
transformer should be connected via a dedicated PC board
track 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 resistor should be
used. In this case, all the noise sensitive low current ground
tracks 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 LM5026 should
have short direct paths to the power MOSFETs in order to
minimize inductance in the PC board traces.
The two ground pins (AGND, PGND) must be connected together with a short direct connection to avoid jitter due to
relative ground bounce.
If the internal dissipation of the LM5026 produces high junction temperatures during normal operation, the use of multiple
vias under the IC to a ground place can help conduct heat
away from the IC. Judicious positioning of the PC board within
the end product, along with use of any available air flow
(forced or natural convection) can help reduce the junction
temperatures.
Application Circuit Example
The following schematic shows an example of an LM5026
controlled 100W active clamp forward power converter. The
input voltage range (VPWR) is 36V to 78V, and the output voltage is 3.3V. The output current capability is 30 Amps. Current
sense transformer T2 provides information to the CS pin for
current mode control and current limit protection. The error
amplifiers and reference U3 and U4 provide voltage feedback
via optocoupler U2. Synchronous rectifiers Q3-Q6 minimize
rectification losses in the secondary. An auxiliary winding on
inductor L2 provides power to the LM5026 VCC pin when the
output is in regulation. The input voltage UVLO levels are
≈34V for increasing VPWR, and ≈32V for decreasing VPWR.
The circuit can be shut down by forcing the ON/OFF input (J2)
below 1.25V. An external synchronizing frequency can be applied to the SYNC input (J11) or like converters can be selfsynchronized by connections of (J3). The regulator output is
current limited at ≈32A.
20147931
FIGURE 17. Altering the Slope of Duty Cycle vs. VPWR
Programmable Maximum Duty Cycle Clamp (DCL)
When the UVLO pin is biased at 1.25V (minimum operating
level), the maximum duty cycle of OUT_A is limited by the
duty cycle of the internal clock signal. The duty cycle of the
internal clock can be adjusted by programming a voltage set
at the DCL pin. The default maximum duty cycle (80%) can
be selected by connecting the DCL pin to the RT pin. The DCL
pin should not be left open. A small decoupling capacitor located close to the DCL pin is recommended.
The oscillator frequency set resistance (RT) must be determined first before programming the maximum duty cycle.
Following the selection of the total RT resistance, the ratio of
the RT resistors can be designed to set the desired maximum
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18
FIGURE 18. Application Circuit: Input 36-78V, Output 3.3V, 30A
20147932
LM5026
19
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LM5026
Physical Dimensions inches (millimeters) unless otherwise noted
Molded TSSOP-16
NS Package Number MTC16
Note: It is recommended that the exposed pad be connected to Pin 11 (AGND).
16-Lead LLP Surface Mount Package
NS Package Number SDA16A
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LM5026
Notes
21
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LM5026 Active Clamp Current Mode PWM Controller
Notes
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