NSC LM5070MTCX-80

LM5070
Integrated Power Over Ethernet PD Interface and PWM
Controller
General Description
The LM5070 power interface port and pulse width modulation (PWM) controller provides a complete integrated solution for Powered Devices (PD) that connect into Power over
Ethernet (PoE) systems. The LM5070 integrates an 80V,
400mA line connection switch and associated control for a
fully IEEE 802.3af compliant interface with a full featured
current mode pulse width modulator dc-dc converter. All
power sequencing requirements between the controller interface and switch mode power supply (SMPS) are integrated into the IC. Two options are available providing either
an 80% maximum duty cycle limit with slope compensation
(on the –80 suffix) device or a 50% maximum duty cycle limit
and no slope compensation on the (–50 suffix) device.
Features
n
n
n
n
Fully Compliant 802.3af Power Interface Port
80V, 1Ω, 400 mA Internal MOSFET
Programmable Inrush Current Limit
Detection Resistor Disconnect Function
n Programmable Classification Current
n Programmable Under-voltage Lockout with
Programmable Hysteresis
n Thermal Shutdown Protection
n Current Mode Pulse Width Modulator
n Supports both Isolated and Non-Isolated Applications
n Error Amplifier and Reference for Non-Isolated
Applications
n Programmable Oscillator Frequency
n Programmable Soft-start
n 80% Maximum Duty Cycle Limiter, Slope Compensation
(-80 device)
n 50% Maximum Duty Cycle Limiter, No Slope
Compensation (-50 device)
n 800 mA Peak Gate Driver
Packages
n TSSOP-16
n LLP-16 (5 mm x 5 mm)
20120001
© 2004 National Semiconductor Corporation
DS201200
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LM5070 Integrated Power Over Ethernet PD Interface and PWM Controller
December 2004
LM5070
20120002
FIGURE 1. Simplified Block Diagram
Connection Diagram
20120003
16 Lead TSSOP, LLP
Ordering Information
Order Number
Description
NSC Package Type /
Drawing
Supplied As
LM5070MTC-50
50% Duty Cycle Limit
TSSOP-16/MTC-16
92 units per rail
LM5070MTCX-50
50% Duty Cycle Limit
TSSOP-16/MTC-16
2500 units on tape and reel
LM5070SD-50
50% Duty Cycle Limit
LLP-16/SDA-16
Available Soon
LM5070SDX-50
50% Duty Cycle Limit
LLP-16/SDA-16
Available Soon
LM5070MTC-80
80% Duty Cycle Limit
TSSOP-16/MTC-16
92 units per rail
LM5070MTCX-80
80% Duty Cycle Limit
TSSOP-16/MTC-16
2500 units on tape and reel
LM5070SD-80
80% Duty Cycle Limit
LLP-16/SDA-16
Available Soon
LM5070SDX-80
80% Duty Cycle Limit
LLP-16/SDA-16
Available Soon
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2
LM5070
Pin Description
PIN
NAME
1
VIN
2
RSIG
3
RCLASS
4
UVLO
5
DESCRIPTION
APPLICATION INFORMATION
System high potential input.
The diode “OR” of several lines entering the PD, it is the more
positive input potential.
Signature resistor pin.
Connect a 25kΩ signature resistor from VIN to this pin for signature
detection.
Classification resistor pin.
Connect the classification programming resistor from this pin to
VEE.
Line under-voltage lockout.
An external resistor divider from VIN to UVLORTN programs the
shutdown levels with a 2.00V threshold at the UVLO pin.
Hysteresis is set by a switched internal 10uA current source that
forces additional current into the resistor divider.
UVLORTN Return for the external UVLO resistors, if Connect the bottom resistor of the resistor divider between the
used.
UVLO pin and this pin.
6
RCLP
Current limit programming pin.
Programs the inrush current limit for the device. If left open, the
inrush current limit will default to 400mA max.
7
VEE
System low potential input.
Diode “OR’d” to the RJ45 connector and PSE’s –48V supply, it is
the more negative input potential.
8
RTN
System return for the PWM converter.
The drain of the internal current limiting power MOSFET which
connects VEE to the return path of the dc-dc converter.
9
OUT
Output of the PWM controller.
DC-DC converter gate driver output with 800mA peak sink current
capability.
10
VCC
Output of the internal high voltage series
pass regulator. Regulated output voltage
is nominally 7.8V.
When the auxiliary transformer winding (if used) raises the voltage
on this pin above the regulation set point, the internal series pass
regulator will shutdown, reducing the controller power dissipation.
11
FB
Feedback signal.
Inverting input of the internal error amplifier. The non-inverting
input is internally connected to a 1.25V reference.
12
COMP
The output of the error amplifier and
input to the Pulse Width Modulator.
COMP pull-up is provided by an internal 5K resistor which may be
used to bias an opto-coupler transistor.
13
CS
Current sense input.
Current sense input for current mode control and over-current
protection. Current limiting is accomplished using a dedicated
current sense comparator. If the CS pin voltage exceeds 0.5V the
OUT pin switches low for cycle-by-cycle current limiting. CS is held
low for 50ns after OUT switches high to blank leading edge current
spikes.
RT / SYNC Oscillator timing resistor pin and
synchronization input.
An external resistor connected from RT to ARTN sets the oscillator
frequency. This pin will also accept narrow ac-coupled
synchronization pulses from an external clock.
14
15
SS
16
ARTN
—
EP
Soft-start input.
An external capacitor and an internal 10uA current source set the
soft-start ramp rate.
Analog PWM supply return.
RTN for sensitive analog circuitry including the SMPS current limit
amplifier.
Exposed PAD, underside of the LLP
package option.
Internally bonded to the die substrate. Connect to VEE potential for
low thermal impedance.
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LM5070
Absolute Maximum Ratings (Note 1)
Human Body Model
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
VIN ,RTN to VEE
-0.3V to 80V
RSIG to VIN
-12V to 0V
UVLO to VEE
-0.3V to 57V
UVLORTN
-0.3V to 13V
RCLASS, RCLP to VEE
-0.3V to 0.3V
VCC, OUT to ARTN
-0.3V to 16V
All other inputs to ARTN
Storage Temperature
-65˚C to +150˚C
Junction Temperature
150˚C
Lead Temperature (Note 2)
Wave (4 seconds)
Infrared (10 seconds)
Vapor Phase (75 seconds)
260˚C
240˚C
219˚C
Operating Ratings
-0.3V to 7V
ARTN to RTN
2000V
VIN voltage
-0.3V to 7V
ESD Rating
1.8V to 75V
External voltage applied to VCC
8.1V to 15V
Operating Junction Temperature
-40˚C to +125˚C
Electrical Characteristics (Note 3)
Specifications in standard type face are for TJ= +25˚C and those in boldface type apply over the full operating junction temperature range. Unless otherwise specified: VIN = 48V, VCC = 10V, RT = 30.3kΩ.
Symbol
Parameter
Conditions
Min
Typ
Max
Units
Powered Interface
IOS
Offset Current
VIN < 10.0V
10
V
VCLSS(ON)
Signature Resistor Disable /
Classification Current Turn On
VIN with respect to VEE
10.0
11.5
12.5
V
VCLSS(OFF) Classification Current Turn Off
VIN with respect to VEE
20.5
22.0
23.0
V
1.43
Classification Voltage
With respect to VEE
ICLASS
Supply Current During
Classification
VIN =17V
IDC
Supply Current During Normal
Operation
OUT floating
UVLO Pin Reference Voltage
VIN > 12V
1.95
UVLO Hysteresis Current
VIN > UVLO
Softstart Release
RTN falling with respect
to VEE
Softstart Release Hysteresis
RTN rising with respect
to VEE
RDS(ON)
PowerFET Resistance
I = 350mA,
VIN = 48V
ILEAK
SMPS Bias Current
VEE = 0V, VIN = RTN =
57V
ILIM
Default Current Limit
VEE = 0V, RTN = 3.0V,
Temp = 0˚C to 85˚C
350
ILIM
Default Current Limit
VEE = 0V, RTN = 3.0V,
Temp = -40˚C to 125˚C
325
Current Limit Programming
Accuracy
VEE = 0V, RTN = 3.0V,
RCLP = 80.6kΩ
-20
VCC Regulation
Open ckt
7.5
7.8
VCC Current Limit
(Note 4)
15
20
1.5
1.57
V
0.5
1.5
mA
1
1.9
mA
2.00
2.05
V
8.0
10
11.5
uA
1.2
1.45
1.7
V
0.8
1.1
1.3
V
1
2.2
Ω
100
uA
390
420
mA
390
420
mA
+20
%
8.1
V
Startup Regulator
VccReg
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4
mA
(Continued)
Specifications in standard type face are for TJ= +25˚C and those in boldface type apply over the full operating junction temperature range. Unless otherwise specified: VIN = 48V, VCC = 10V, RT = 30.3kΩ.
Symbol
Parameter
Conditions
Min
Typ
Max
Units
VccReg –
300mV
VccReg –
100mV
5.9
6.25
6.6
V
1.5
3
mA
VCC Supply
VCC UVLO (Rising)
VCC UVLO (Falling)
Supply Current (Icc)
Cload = 0
Error Amplifier
GBW
Gain Bandwidth
4
DC Gain
75
Input Voltage
FB = COMP
1.219
1.212
COMP Sink Capability
FB=1.5V COMP=1V
ILIM Delay to Output
CS step from 0 to 0.6V,
time to onset of OUT
transition (90%)
5
MHz
dB
1.281
1.288
V
20
mA
20
ns
Current Limit
Cycle by Cycle Current Limit
Threshold Voltage
0.44
0.5
0.56
V
Leading Edge Blanking Time
55
CS Sink Impedance (clocked)
25
55
ns
Ω
7
10
13
uA
Frequency1
(RT = 30.3K)
175
200
225
KHz
Frequency2
(RT = 10.5K)
505
580
665
KHz
3.1
3.8
V
Softstart
Softstart Current Source
Oscillator(Note 5)
Sync threshold
PWM Comparator
Delay to Output
COMP set to 2V
CS stepped 0 to 0.4V,
time to onset of OUT
transition low
Min Duty Cycle
COMP=0V
25
ns
0
%
Max Duty Cycle (-80 Device)
80
%
Max Duty Cycle (-50 Device)
50
%
COMP to PWM Comparator
Gain
0.33
COMP Open Circuit Voltage
COMP Short Circuit Current
COMP= 0V
4.5
5.4
6.3
V
0.6
1.1
1.5
mA
Slope Compensation
Slope Comp Amplitude
(LM5070-80 Device Only)
Delta increase at PWM
Comparator to CS
105
mV
Output High Saturation
Iout = 50mA,
VCC - VOUT
0.25
0.75
Output Low Saturation
Iout = 100mA
0.25
0.75
Rise time
Cload = 1nF
15
ns
Fall time
Cload = 1nF
15
ns
Output Section
5
V
V
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LM5070
Electrical Characteristics (Note 3)
LM5070
Electrical Characteristics (Note 3)
(Continued)
Specifications in standard type face are for TJ= +25˚C and those in boldface type apply over the full operating junction temperature range. Unless otherwise specified: VIN = 48V, VCC = 10V, RT = 30.3kΩ.
Symbol
Parameter
Conditions
Min
Typ
Max
Units
Thermal Shutdown
Tsd
Thermal Shutdown Temp.
165
˚C
25
˚C
MTC Package
125
˚C/W
SDA Package
32
˚C/W
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: For detailed information on soldering plastic TSSOP and LLP package, refer to the Packaging Databook available from National Semiconductor.
Note 3: Min and Max limits are 100% production tested at 25 ˚C. 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.
Note 5: Specification applies to the oscillator frequency. The operational frequency of the LM5070-50 devices is divided by two.
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Default Current Limit vs Temperature
Inrush Current Limit vs RCLP Resistor
20120010
20120009
Oscillator Frequency vs RT Resistance
UVLO Hysteresis Current vs Temperature
20120013
20120008
Softstart Current vs Temperature
Error Amp Input Voltage vs temperature
20120015
20120017
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LM5070
Typical Performance Characteristics
LM5070
Typical Performance Characteristics
(Continued)
Oscillator Frequency vs Temperature
RT = 15.2 kΩ
VCC vs ICC
20120012
20120014
Input Current vs Input Voltage
UVLO Threshold vs Temperature
20120007
20120006
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LM5070
20120004
FIGURE 2. Top Level Block Diagram
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LM5070
20120005
FIGURE 3. PWM Controller Block Diagram
current-mode control for dc-dc converter topologies requiring
a single drive output, such as Flyback and Forward topologies. The LM5070 PWM enables all of the advantages of
current-mode control including line feed-forward, cycle-bycycle current limit and simplified loop compensation. The
oscillator ramp is internally buffered and added to the PWM
comparator input ramp to provide slope compensation necessary for current mode control at duty cycles greater than
50% (-80 suffix only).
Detailed Operating Description
The LM5070 power interface port and pulse width modulation (PWM) controller provides a complete integrated solution for Powered Devices (PD) that connect into Power over
Ethernet (PoE) systems. Major features of the PD interface
portion of the IC include detection, classification, programmable inrush current limit, thermal limit, programmable undervoltage lockout, and current limit monitoring. The device
also includes a high-voltage start-up bias regulator that operates over a wide input range up to 75V. The switch mode
power supply (SMPS) control portion of the IC includes
power good sensing, VCC regulator under-voltage lockout,
cycle-by-cycle current limit, error amplifier, slope compensation, softstart, and oscillator sync capability. This high speed
BiCMOS IC has total propagation delays less than 100ns
and a 1MHz capable oscillator programmed by a single
external resistor. The LM5070 PWM controller provides
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Modes of Operation
The LM5070 PD interface is designed to provide a fully
compliant IEEE 802.3af system. As such, the modes of
operation take into account the barrel rectifiers often utilized
to correctly polarize the dc input from the Ethernet cable.
Table 1 shows the LM5070 operating modes and associated
input voltage range.
10
Input Voltage
VIN wrt VEE
Mode of
Operation
1.8V to 10.0V
Detection
(Signature)
12.5V to 20.5V
Classification
23.0V to UVLO
Rising Vth
Awaiting Full
Power
75V to UVLO
Falling Vth
Normal Powered
Operation
TABLE 2. Classification Levels and Required External
Resistors
An external signature resistor is connected to VEE when VIN
exceeds 1.8V, initiating detection mode. During detection
mode, quiescent current drawn by the LM5070 is less than
10uA. Between 10.0V and 12.5V, the device enters classification mode and the signature resistor is disabled. The
nominal range for classification mode is 11.5V to 21.5V. The
classification current is turned off once the classification
range voltage is exceeded, to reduce power dissipation.
Between 21.5V and UVLO release, the device is in a
standby state, awaiting the input voltage to reach the operational range to complete the power up sequence. Once the
VIN voltage increases above the upper UVLO threshold voltage, the internal power MOSFET is enabled to deliver a
constant current to charge the input capacitor of the dc-dc
converter. When the MOSFET Vds voltage falls below 1.5V,
the internal Power Good signal enables the SMPS controller.
The LM5070 is specified to operate with an input voltage as
high as 75V. The SMPS controller and internal MOSFET are
disabled when VIN falls to the lower UVLO threshold.
Class
PMIN
PMAX
0
0.44W
12.95W
0mA
4mA
Open
1
0.44W
3.84W
9mA
12mA
150Ω
2
3.84W
6.49W
17mA
20mA
82.5Ω
3
6.49W
12.95W
26mA
30mA
53.6Ω
36mA
44mA
38.3Ω
4
Reserved Reserved
ICLASS ICLASS RCLASS
(MIN)
(MAX)
Undervoltage Lockout (UVLO)
The IEEE 802.3af specification states that the PSE will
supply power to the PD within 400ms after completion of
detection. The LM5070 contains a programmable line Under
Voltage Lock Out (UVLO) circuit. The first resistor should be
connected between the VIN to UVLO pins; the bottom resistor in the divider should be connected between the UVLO
and UVLORTN pins. The bottom resistor should not be tied
to VEE because any current from VIN to VEE will cause the
system to violate the 10uA maximum offset current specification during detection mode.
The divider must be designed such that the voltage at the
UVLO pin equals 2.0V when VIN reaches the desired minimum operating level. If the UVLO threshold is not met, the
interface control and SMPS control will remain in standby.
UVLO hysteresis is accomplished with an internal 10uA
current source that is switched on and off into the impedance
of the UVLO 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 2.00V threshold, the current source is turned
off, causing the voltage at the UVLO pin to fall. The LM5070
UVLO thresholds cannot be programmed lower than 23V,
otherwise the device would operate in classification mode
with both the classification current source and the SMPS
enabled. The combined power dissipation of these two functions could exceed the maximum power dissipation of the
package.
There are many additional uses for the UVLO pin. The UVLO
function can also be used to implement a remote enable /
disable function. Pulling the UVLO pin down below the
UVLO threshold disables the interface and SMPS controller.
Detection Signature
To detect a potential powered device candidate, the PSE will
apply a voltage from 2.8V to 10V across the input terminals
of the PD. The voltage can be of either polarity so a diode
barrel network is required on both lines to ensure this capability. The PSE will take two measurements, separated by at
least 1V and 2ms of time. The voltage ramp between measurement points will not exceed 0.1V/us. The delta voltage /
delta current calculation is then performed; if the detected
impedance is above 23.75kΩ and below 26.25kΩ, the PSE
will consider a PD to be present. If the impedance is less
than 15kΩ or greater than 33kΩ a PD will be considered not
present and will not receive power. Impedances between
these values may or may not indicate the presence of a valid
PD. The LM5070 will enable the signature resistor at a
controller input voltage of 1.5V to take into account the diode
voltage drops. The PSE will tolerate no more than 1.9V of
offset voltage (caused by the external diodes) or more than
10uA of offset current (bias current). The input capacitance
must be greater than 0.05uF and less than 0.12uF. To increase efficiency, the signature resistor is disabled by the
LM5070 controller once the input voltage is above the detection range ( > 11V).
Classification
To classify the PD, the PSE will present a voltage between
14.5V and 20.5V to the PD. The LM5070 enables classification mode at a nominal input voltage of 11.5V. An internal
1.5V linear regulator and an external resistor connected to
the RCLASS pin provide classification programming current.
Table 2 shows the external classification resistor required for
a particular class.
Power Supply Operation / Current
Limit Programming
Once the UVLO threshold has been satisfied, the interface
controller of the LM5070 will charge up the SMPS input
capacitor through the internal power MOSFET. This load
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LM5070
The classification current flows through the IC into the classification resistor. The suggested resistor values take into
account the bias current flowing into the IC. A different
desired RCLASS can be calculated by dividing 1.5V by the
desired classification current.
Per the IEEE 802.3af specification, classification is optional,
and the PSE will default to class 0 if a valid classification
current is not detected. If PD classification is not desired
(i.e., Class 0), simply leave the RCLASS pin open. The
classification time period may not last longer then 75ms as
per IEEE 802.3af. The LM5070 will remain in classification
mode until VIN is greater than 22V.
TABLE 1. Operating Modes With Respect to Input
Voltage
LM5070
Power Supply Operation / Current
Limit Programming (Continued)
Error Amplifier
An internal high gain error amplifier is provided within the
LM5070. The amplifier’s non-inverting reference is set to a
fixed reference voltage of 1.25V. The inverting input is connected to the FB pin. In non-isolated applications, the power
converter output is connected to the FB pin via voltage
scaling resistors. Loop compensation components are connected between the COMP and FB pins. For most isolated
applications the error amplifier function is implemented on
the secondary side of the converter and the internal error
amplifier is not used. The internal error amplifier is configured as an open drain output and can be disabled by connecting the FB pin to ARTN. An internal 5K pull-up resistor
between a 5V reference and COMP can be used as the
pull-up for an optocoupler in isolated applications.
capacitance provides input filtering for the power converter
section and must be at least 5uF per the IEEE 802.3af
specification. To accomplish the charging in a controlled
manner, the power MOSFET is current limited to 375mA.
The IEEE 802.3af specification requires that the load capacitance be charged within 75ms.
Some legacy PSEs may not be able to supply the IEEE
maximum power of 15W to the PD, and this can be a
problem during startup. Low power PDs that are used in
these legacy systems will require a lower startup current
limit. The LM5070 can be programmed for a reduced inrush
current limit level with a resistor at RCLP pin. The programmable inrush current limit range is 75mA to 390mA. If the
RCLP pin is left open, the LM5070 will default to 390mA,
near the maximum allowed per the IEEE 802.3 specification.
To set a desired inrush current limit (limit), the RCLP resistor
can be calculated from:
Current Limit / Current Sense
The LM5070 provides a cycle-by-cycle over current protection function. Current limit is accomplished by an internal
current sense comparator. If the voltage at the current sense
comparator input CS exceeds 0.5V with respect to RTN/
ARTN, the output pulse will be immediately terminated. A
small RC filter, located near the CS pin of the controller, is
recommended to filter noise from the current sense signal.
The CS input has an internal MOSFET which discharges the
CS pin capacitance at the conclusion of every cycle. The
discharge device remains on an additional 50ns after the
beginning of the new cycle to attenuate the leading edge
spike on the current sense signal.
The LM5070 current sense and PWM comparators are 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 located very close to the device and connected
directly to the pins of the controller (CS and ARTN). If a
current sense transformer is used, both leads of the transformer secondary should be routed to the sense resistor and
the current sense filter network. A sense resistor located in
the source of the primary power MOSFET may be used for
current sensing, but a low inductance resistor is required.
When designing with a current sense resistor, all of the noise
sensitive low power ground connections should be connected together local to the controller and a single connection should be made to the high current power return (sense
resistor ground point).
The SMPS controller will not initiate operation until the load
capacitor is completely charged. The power sequencing between the interface circuitry and the SMPS controller occurs
automatically within the LM5070. Detection circuitry monitors
the RTN pin to detect interface startup completion. When the
RTN pin potential drops below 1.5V with respect to VEE, the
VCC regulator of the SMPS controller is enabled. The softstart function is enabled once the VCC regulator achieves
minimum operating voltage. The RCLP programmed inrush
current limit only applies to the initial charging phase. The
interface power MOSFET current limit will revert to the fixed
default protection current limit of 390mA once the SMPS is
powered up and the soft-start pin sequence begins.
High Voltage Start-up Regulator
The LM5070 contains an internal high voltage startup regulator that allows the input pin (VIN
IN) to be connected directly to line voltages as high as 75V.
The regulator output is internally current limited to 15mA.
The recommended capacitance range for the VCC regulator
output is 0.1uF to 10uF. When the voltage on the V CC pin
reaches the regulation point of 7.8V, the controller output is
enabled. The controller will remain enabled until VCC falls
below 6.25V.
In typical applications, a transformer auxiliary winding is
diode connected to the VCC pin. This winding should raise
the VCC voltage above 8.1V to shut off the internal startup
regulator. Though not required, powering VCC from an auxiliary winding improves conversion efficiency while reducing
the power dissipated in the controller. The external VCC
capacitor must be selected such that the capacitor maintains
the VCC voltage greater than the VCC UVLO falling threshold
(6.25V) during the initial start-up. During a fault condition
when the converter auxiliary winding is inactive, external
current draw on the VCC line should be limited such that the
power dissipated in the start-up regulator does not exceed
the maximum power dissipation capability of the LM5070
package.
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Oscillator, Shutdown and Sync
Capability
A single external resistor connected between the RT and
ARTN pins sets the LM5070 oscillator frequency. Internal to
the LM5070–50 device (50% duty cycle limited option) is an
oscillator divide by two circuit. This divide by two circuit
creates an exact 50% duty cycle clock which is used internally to create a precise 50% duty cycle limit function. Because of this divide by two, the internal oscillator actually
operates at twice the frequency of the output (OUT). For the
LM5070–80 device the oscillator frequency and the operational output frequency are the same. To set a desired output
operational frequency (F), the RT resistor can be calculated
from:
LM5070-80:
12
tor between the CS pin and current sense resistor). Since
the LM5070-50 is not capable of duty cycles greater than
50%, there is no slope compensation feature in this device.
Softstart
The softstart feature allows the power converter to gradually
reach the initial steady state operating point, thereby reducing start-up stresses, output overshoot and current surges.
At power on, after the VCC undervoltage lockout threshold is
satisfied, an internal 10µA current source charges an external capacitor connected to the SS pin. The capacitor voltage
will ramp up slowly and will limit the COMP pin voltage and
the duty cycle of the output pulses.
LM5070-50:
The LM5070 can also be synchronized to an external clock.
The external clock must have a higher frequency than the
free running oscillator frequency set by the RT resistor. The
clock signal should be capacitively coupled into the RT pin
with a 100pF capacitor. A peak voltage level greater than 3.7
volts at the RT pin is required for detection of the sync pulse.
The sync pulse width should be set between 15 to 150ns by
the external components. The RT resistor is always required,
whether the oscillator is free running or externally synchronized. The voltage at the RT pin is internally regulated to a 2
volts. The RT resistor should be located very close to the
device and connected directly to the pins of the controller
(RT and ARTN).
Gate Driver and Maximum Duty
Cycle Limit
The LM5070 provides an internal gate driver (OUT), which
can source and sink a peak current of 800mA. The LM5070
is available in two duty cycle limit options. The maximum
output duty cycle is typically 80% for the LM5070-80 option
and precisely equal to 50% for the LM5070-50 option. The
maximum duty cycle function for the LM5070-50 is accomplished with an internal toggle flip-flop which ensures an
accurate duty cycle limit. The internal oscillator frequency of
the LM5070-50 is therefore twice the operating frequency of
the PWM controller (OUT pin).
The 80% maximum duty cycle limit of the LM5070-80 is
determined by the internal oscillator and varies more than
the 50% limit of the LM5070-50. For the LM5070-80, the
internal oscillator frequency and the operational frequency of
the PWM controller are equal.
PWM Comparator / Slope
Compensation
The PWM comparator compares the current ramp signal
with the loop error voltage derived from the error amplifier
output. The error amplifier output voltage at the COMP pin is
offset by 1.4V and then further attenuated by a 3:1 resistor
divider. The PWM comparator polarity is such that 0 Volts on
the COMP pin will result in zero duty cycle at the controller
output. 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 LM5070-80 integrates this slope
compensation by summing a current ramp generated by the
oscillator with the current sense signal. Additional slope
compensation may be added by increasing the source impedance of the current sense signal (with an external resis-
Thermal Protection
Internal thermal shutdown circuitry is provided to protect the
integrated circuit in the event the maximum junction temperature is exceeded. This feature prevents catastrophic
failures from accidental device overheating. When activated,
typically at 165 degrees Celsius, the controller is forced into
a low power standby state, disabling the output driver, bias
regulator, main interface pass MOSFET, and classification
regulator if enabled. After the temperature is reduced (typical
hysteresis = 25˚C) the VCC regulator will be enabled and a
softstart sequence initiated.
13
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LM5070
Oscillator, Shutdown and Sync
Capability (Continued)
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14
FIGURE 4.
LM5070 Application Circuit – Isolated Output with Diode Rectification
20120019
LM5070
FIGURE 5.
LM5070 Application Circuit – Isolated Output with Synchronous Rectification
20120021
LM5070
15
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LM5070
Physical Dimensions
inches (millimeters) unless otherwise noted
Package Number MTC16
Package Number SDA16A
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16
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LM5070 Integrated Power Over Ethernet PD Interface and PWM Controller
Notes