LM5117PMHX/NOPB [TI]
Wide Input Range Synchronous Buck Controller with Analog Current Monitor;型号: | LM5117PMHX/NOPB |
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描述: | Wide Input Range Synchronous Buck Controller with Analog Current Monitor |
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LM5117, LM5117-Q1
SNVS698F –APRIL 2011–REVISED AUGUST 2015
LM5117/Q1 Wide Input Range Synchronous Buck Controller with Analog Current Monitor
1 Features
3 Description
The LM5117 is
a synchronous buck controller
1
•
LM5117-Q1 is Qualified for Automotive
Applications
intended for step-down regulator applications from a
high voltage or widely varying input supply. The
control method is based upon current mode control
utilizing an emulated current ramp. Current mode
control provides inherent line feed-forward, cycle-by-
cycle current limiting and ease of loop compensation.
The use of an emulated control ramp reduces noise
sensitivity of the pulse-width modulation circuit,
allowing reliable control of very small duty cycles
necessary in high input voltage applications.
•
AEC-Q100 Qualified With the Following Results:
–
Device Temperature Grade 1: -40°C to 125°C
Ambient Operating Temperature Range
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
Emulated Peak Current Mode Control
Wide Operating Range from 5.5 V to 65 V
Robust 3.3-A Peak Gate Drives
Adaptive Dead-Time Output Driver Control
Free-Run or Synchronizable Clock up to 750 kHz
Optional Diode Emulation Mode
The operating frequency is programmable from 50
kHz to 750 kHz. The LM5117 drives external high-
side and low-side NMOS power switches with
adaptive dead-time control. A user-selectable diode
emulation mode enables discontinuous mode
operation for improved efficiency at light load
conditions. A high voltage bias regulator that allows
external bias supply further improves efficiency. The
LM5117’s unique analog telemetry feature provides
average output current information. Additional
features include thermal shutdown, frequency
synchronization, hiccup mode current limit, and
adjustable line undervoltage lockout.
Programmable Output from 0.8 V
Precision 1.5% Voltage Reference
Analog Current Monitor
Programmable Current Limit
Hiccup Mode Overcurrent Protection
Programmable Soft-Start and Tracking
Programmable Line Undervoltage Lockout
Programmable Switchover to External Bias Supply
Thermal Shutdown
Device Information(1)
2 Applications
PART NUMBER
LM5117
LM5117-Q1
PACKAGE
HTSSOP (20) PWP 6.50 mm × 4.40 mm
WQFN (24) RTW 4.00 mm × 4.00 mm
BODY SIZE (NOM)
•
•
•
•
Automotive Infotainment
Industrial DC-DC Motor Drivers
Automotive USB Power
Telecom Server
(1) For all available packages, see the orderable addendum at
the end of the datasheet.
Typical Application
V
IN
UVLO
VIN
DEMB
VCC
HB
SW
RAMP
LM5117
V
OUT
HO
SW
LO
V
OUT
VCCDIS
COMP
FB
CS
CM
CSG
RT RES SS AGND PGND
1
An IMPORTANT NOTICE at the end of this data sheet addresses availability, warranty, changes, use in safety-critical applications,
intellectual property matters and other important disclaimers. PRODUCTION DATA.
LM5117, LM5117-Q1
SNVS698F –APRIL 2011–REVISED AUGUST 2015
www.ti.com
Table of Contents
7.3 Feature Description................................................. 13
7.4 Device Functional Modes........................................ 21
Application and Implementation ........................ 22
8.1 Application Information............................................ 22
8.2 Typical Applications ............................................... 22
8.3 Detailed Design Procedure ..................................... 22
8.4 Application Curves .................................................. 32
Power Supply Recommendations...................... 35
1
2
3
4
5
6
Features.................................................................. 1
Applications ........................................................... 1
Description ............................................................. 1
Revision History..................................................... 2
Pin Configuration and Functions......................... 3
Specifications......................................................... 5
6.1 Absolute Maximum Ratings ..................................... 5
6.2 ESD Ratings (LM5117)............................................. 5
6.3 ESD Ratings (LM5117-Q1) ....................................... 5
6.4 Recommended Operating Conditions....................... 6
6.5 Thermal Information.................................................. 6
6.6 Electrical Characteristics........................................... 7
6.7 Switching Characteristics.......................................... 8
6.8 Typical Characteristics.............................................. 9
Detailed Description ............................................ 11
7.1 Overview ................................................................. 11
7.2 Functional Block Diagram ....................................... 12
8
9
10 Layout................................................................... 35
10.1 Layout Guideline ................................................... 35
11 Device and Documentation Support ................. 36
11.1 Related Links ........................................................ 36
11.2 Community Resources.......................................... 36
11.3 Trademarks........................................................... 36
11.4 Electrostatic Discharge Caution............................ 36
11.5 Glossary................................................................ 36
7
12 Mechanical, Packaging, and Orderable
Information ........................................................... 36
4 Revision History
NOTE: Page numbers for previous revisions may differ from page numbers in the current version.
Changes from Revision E (March 2013) to Revision F
Page
•
Added Device Information and Pin Configuration and Functions sections, ESD Rating table, Feature Description,
Device Functional Modes, Application and Implementation, Power Supply Recommendations, Layout, Device and
Documentation Support , and Mechanical, Packaging, and Orderable Information sections ................................................ 1
•
Changed µH into µF ............................................................................................................................................................ 29
Changes from Revision D (March 2013) to Revision E
Page
•
Changed layout of National Data Sheet to TI format ........................................................................................................... 34
2
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SNVS698F –APRIL 2011–REVISED AUGUST 2015
5 Pin Configuration and Functions
PWP Package
20-Pin HTSSOP
Top View
UVLO
DEMB
RES
1
2
3
4
5
6
7
8
9
20
19
18
17
16
15
14
13
12
11
VIN
HB
HO
SS
SW
RT
VCC
LO
EP
AGND
VCCDIS
FB
PGND
CSG
CS
COMP
10
CM
RAMP
RTW Package
24-Pin WQFN
Top View
24
23
22
21
20
19
DEMB
RES
SS
1
2
3
4
5
6
18
17
16
15
14
13
SW
NC
VCC
LO
EP
RT
AGND
NC
PGND
CSG
7
8
9
10
11
12
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SNVS698F –APRIL 2011–REVISED AUGUST 2015
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Pin Functions
PIN
(1)
TYPE
DESCRIPTION
HTSSOP WQFN
NAME
1
24
UVLO
Undervoltage lockout programming pin. If the UVLO pin voltage is below 0.4 V, the
regulator is in the shutdown mode with all functions disabled. If the UVLO pin voltage is
greater than 0.4 V and less than 1.25 V, the regulator is in standby mode with the VCC
regulator operational, the SS pin grounded, and no switching at the HO and LO outputs.
If the UVLO pin voltage is above 1.25 V, the SS pin is allowed to ramp and pulse width
modulated gate drive signals are delivered to the HO and LO pins. A 20μA current
source is enabled when UVLO exceeds 1.25 V and flows through the external UVLO
resistors to provide hysteresis.
I
2
3
1
2
DEMB
RES
Optional logic input that enables diode emulation when in the low state. In diode
emulation mode, the low-side NMOS is latched off for the remainder of the PWM cycle
after detecting reverse current flow (current flow from output to ground through the low-
side NMOS). When DEMB is high, diode emulation is disabled allowing current to flow in
either direction through the low-side NMOS. A 50-kΩ pull-down resistor internal to the
LM5117 holds DEMB pin low and enables diode emulation if the pin is left floating.
I
The restart timer pin that configures the hiccup mode current limiting. A capacitor on the
RES pin determines the time the controller remains off before automatically restarting.
The hiccup mode commences when the controller experiences 256 consecutive PWM
cycles of cycle-by-cycle current limiting. After this occurs, a 10-μA current source
charges the RES pin capacitor to the 1.25 V threshold and restarts LM5117.
O
I
4
5
3
4
SS
RT
An external capacitor and an internal 10-μA current source set the ramp rate of the error
amplifier reference during soft-start. The SS pin is held low when VCC< 5 V, UVLO <
1.25 V or during thermal shutdown.
The internal oscillator is programmed with a single resistor between RT and the AGND.
The recommended maximum oscillator frequency is 750kHz. The internal oscillator can
be synchronized to an external clock by coupling a positive pulse into the RT pin through
a small coupling capacitor.
I
6
7
5
7
AGND
G
Analog ground. Return for the internal 0.8 V voltage reference and analog circuits.
VCCDIS
Optional input that disables the internal VCC regulator. If VCCDIS>1.25 V, the internal
VCC regulator is disabled. VCCDIS has an internal 500-kΩ pulldown resistor to enable
the VCC regulator when the pin is left floating. The internal 500-kΩ pull-down resistor can
be overridden by pulling VCCDIS above 1.25 V with a resistor divider connected to an
external bias supply.
I
8
9
8
9
FB
Feedback. Inverting input of the internal error amplifier. A resistor divider from the output
to this pin sets the output voltage level. The regulation threshold at the FB pin is 0.8 V.
I
COMP
CM
Output of the internal error amplifier. The loop compensation network should be
connected between this pin and the FB pin.
O
O
10
11
10
11
Current monitor output. Average of the sensed inductor current is provided. Monitor
directly between CM and AGND. CM should be left floating when the pin is not used.
RAMP
PWM ramp signal. An external resistor and capacitor connected between the SW pin, the
RAMP pin and the AGND pin sets the PWM ramp slope. Proper selection of component
values produces a RAMP signal that emulates the AC component of the inductor with a
slope proportional to input supply voltage.
I
12
13
12
13
CS
I
Current sense amplifier input. Connect to the high-side of the current sense resistor.
CSG
Kelvin ground connection to the current sense resistor. Connect directly to the low-side of
the current sense resistor.
G
14
15
16
17
14
15
16
18
PGND
LO
Power ground return pin for low-side NMOS gate driver. Connect directly to the low-side
of the current sense resistor.
O
Low-side NMOS gate drive output. Connect to the gate of the low-side synchronous
NMOS transistor through a short, low inductance path.
P/O/I
I/O
VCC
SW
Bias supply pin. Locally decouple to PGND using a low ESR/ESL capacitor located as
close to controller as possible.
Switching node of the buck regulator. Connect to the bootstrap capacitor, the source
terminal of the high-side NMOS transistor and the drain terminal of the low-side NMOS
through a short, low inductance path.
O
P
18
19
HO
High-side NMOS gate drive output. Connect to the gate of the high-side NMOS transistor
through a short, low inductance path.
(1) I = Input, O = Output, G = Ground, P = Power
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SNVS698F –APRIL 2011–REVISED AUGUST 2015
Pin Functions (continued)
PIN
HTSSOP WQFN
(1)
TYPE
DESCRIPTION
NAME
19
20
HB
High-side driver supply for the bootstrap gate drive. Connect to the cathode of the
external bootstrap diode and to the bootstrap capacitor. The bootstrap capacitor supplies
current to charge the high-side NMOS gate and should be placed as close to controller
as possible.
P/I
20
22
VIN
EP
P/I
-
Supply voltage input source for the VCC regulator.
EP
EP
Exposed pad of the package. Electrically isolated. Should be soldered to the ground
plane to reduce thermal resistance.
6
NC
NC
NC
NC
-
-
-
-
No electrical contact.
No electrical contact.
No electrical contact.
No electrical contact.
17
21
23
6 Specifications
6.1 Absolute Maximum Ratings
over operating free-air temperature range (unless otherwise noted)(1)
MIN
–0.3
–3.0
–0.3
–0.3
–0.3
–0.3
–0.3
–0.3
–0.3
–0.3
–55
MAX
UNIT
V
VIN to AGND
SW to AGND
HB to SW
75
75
V
15
V
(2)
VCC to AGND
15
V
HO to SW
HB + 0.3
V
LO to AGND
VCC + 0.3
V
FB, DEMB, RES, VCCDIS, UVLO to AGND
CM, COMP to AGND(3)
SS, RAMP, RT to AGND
CS, CSG, PGND, to AGND
Storage Temperature, Tstg
Junction temperature
15
7
V
V
7
V
0.3
150
150
V
°C
°C
–40
(1) Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. These are stress ratings
only, which do not imply functional operation of the device at these or any other conditions beyond those indicated under Recommended
Operating Conditions. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.
(2) See Application and Implementation when input supply voltage is less than the VCC voltage.
(3) These pins are output pins. As such they are not specified to have an external voltage applied.
6.2 ESD Ratings (LM5117)
VALUE
UNIT
Human-body model (HBM), per ANSI/ESDA/JEDEC JS-001(1)
±2000
V
V(ESD)
Electrostatic discharge
Charged-device model (CDM), per JEDEC specification JESD22- V
C101(2)
±750
V
(1) JEDEC document JEP155 states that 500-V HBM allows safe manufacturing with a standard ESD control process.
(2) JEDEC document JEP157 states that 250-V CDM allows safe manufacturing with a standard ESD control process.
6.3 ESD Ratings (LM5117-Q1)
VALUE
UNIT
Human-body model (HBM), per AEC Q100-002(1)
Charged-device model (CDM), per AEC Q100-011
±2000
±750
V
V
V(ESD)
Electrostatic discharge
(1) AEC Q100-002 indicates that HBM stressing shall be in accordance with the ANSI/ESDA/JEDEC JS-001 specification.
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6.4 Recommended Operating Conditions
over operating free-air temperature range (unless otherwise noted)(1)
MIN
5.5
5.5
5.5
-40
MAX
65
UNIT
V
VIN(2)
VCC
14
V
HB to SW
Junction temperature
14
V
125
°C
(1) Recommended Operating Conditions are conditions under which operation of the device is intended to be functional, but does not
ensure specific performance limits. For specifications and test conditions see Electrical Characteristics.
(2) Minimum VIN operating voltage is defined with VCC supplied by the internal HV startup regulator and no external load on VCC. When
VCC is supplied by an external source, minimum VIN operating voltage is 4.5 V.
6.5 Thermal Information
LM5117, LM5117-Q1
THERMAL METRIC(1)
PWP (HTSSOP) RTW (WQFN)
UNIT
20 PINS
24 PINS
RθJA
Junction-to-ambient thermal resistance
Junction-to-case (top) thermal resistance
40
4
40
6
°C/W
°C/W
RθJC(top)
(1) For more information about traditional and new thermal metrics, see the Semiconductor and IC Package Thermal Metrics application
report, SPRA953.
6
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SNVS698F –APRIL 2011–REVISED AUGUST 2015
6.6 Electrical Characteristics
Typical limits are for TJ = 25°C only, represent the most likely parametric norm at TJ = 25°C, and are provided for reference
purposes only; minimum and maximum limits apply over the junction temperature range of –40°C to +125°C. Unless
otherwise specified, the following conditions apply: VVIN = 48 V, VVCCDIS = 0 V, RT = 25 kΩ, no load on LO and HO.
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
VIN SUPPLY
VSS = 0 V
4.8
0.4
16
6.2
0.55
40
mA
mA
µA
(1)
IBIAS
VIN operating current
VSS = 0 V, VVCCDIS = 2 V
VSS = 0 V, VUVLO = 0 V
ISHUTDOWN VIN shutdown current
VCC REGULATOR
VCC(REG)
VCC regulation
No load
6.85
30
7.6
0.05
0.4
42
8.2
0.14
0.5
V
V
VVIN = 5.5 V, No external load
VVIN = 6 V, ICC = 20 mA
VVCC = 0 V
VCC dropout (VIN to VCC)
VCC sourcing current limit
V
mA
mA
VSS = 0 V, VVCCDIS = 2 V
4
5
7.3
(1)
IVCC
VCC operating current
VSS = 0 V, VVCCDIS = 2 V, VVCC = 14
V
5.8
mA
VCC undervoltage threshold
VCC undervoltage hysteresis
VCC rising
4.7
4.9
0.2
5.15
V
V
VCC DISABLE
VCCDIS threshold
VCCDIS rising
VVCCDIS = 0 V
1.22
1.25
0.06
-20
1.29
V
V
VCCDIS hysteresis
VCCDIS input current
VCCDIS pulldown resistance
nA
kΩ
500
UVLO
UVLO threshold
UVLO rising
VUVLO = 1.4 V
UVLO falling
1.22
15
1.25
20
1.29
25
V
µA
V
UVLO hysteresis current
UVLO shutdown threshold
UVLO shutdown hysteresis
0.23
0.3
0.1
V
SOFT START
ISS SS current source
SS pulldown resistance
ERROR AMPLIFIER
VSS = 0 V
7
10
13
12
24
µA
Ω
VREF
FB reference voltage
Measured at FB, FB = COMP
VFB = 0.8 V
788
2.8
800
1
812
mV
nA
V
FB input bias current
COMP output high voltage
COMP output low voltage
DC gain
VOH
VOL
AOL
ƒBW
ISOURCE = 3 mA
ISINK = 3 mA
0.26
V
80
3
dB
MHz
Unity gain bandwidth
PWM COMPARATOR
tHO(OFF) Forced HO Off-time
tON(MIN)
260
320
100
1.2
440
ns
ns
V
Minimum HO On-time
VVIN = 65 V
COMP to PWM comparator offset
OSCILLATOR
ƒSW1
ƒSW2
Frequency 1
RT = 25 kΩ
RT = 10 kΩ
180
430
200
480
1.25
3.2
220
530
kHz
kHz
V
Frequency 2
RT output voltage
RT sync positive threshold
Sync pulse width
2.6
3.95
V
100
ns
(1) Operating current does not include the current into the RT resistor.
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Electrical Characteristics (continued)
Typical limits are for TJ = 25°C only, represent the most likely parametric norm at TJ = 25°C, and are provided for reference
purposes only; minimum and maximum limits apply over the junction temperature range of –40°C to +125°C. Unless
otherwise specified, the following conditions apply: VVIN = 48 V, VVCCDIS = 0 V, RT = 25 kΩ, no load on LO and HO.
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
CURRENT LIMIT
Cycle-by-cycle sense voltage
threshold
VCS(TH)
VRAMP = 0 V, CSG to CS
106
120
135
mV
CS input bias current
VCS = 0 V
–100
–100
-66
-66
10
µA
µA
CSG input bias current
Current sense amplifier gain
Hiccup mode fault timer
VCSG = 0 V
V/V
256
Cycles
RES
IRES
RES Current Source
RES Threshold
10
µA
V
VRES
RES Rising
1.22
2.95
1.25
1.285
1.65
DIODE EMULATION
VIL
VIH
DEMB input low threshold
2
2.5
–5
V
V
DEMB input high threshold
SW zero cross threshold
mV
kΩ
DEMB input pulldown resistance
50
CURRENT MONITOR
Current monitor amplifier gain
CS to CM
17.5
–2
20.5
0
23.5
2
V/V
%
Current monitor amplifier gain
Zero input offset
Drift over Temperature
25
120
mV
HO GATE DRIVER
VOHH
VOLH
HO High-state voltage drop
HO Low-state voltage drop
HO rise time
IHO = –100 mA, VOHH = VHB – VHO
IHO = 100 mA, VOLH = VHO – VSW
C-load = 1000 pF(2)
0.17
0.1
6
0.3
0.2
V
V
ns
ns
A
HO fall time
C-load = 1000pF(2)
5
IOHH
IOLH
Peak HO source current
Peak HO sink current
HB to SW undervoltage
HB DC bias current
VHO = 0 V, SW = 0 V, HB = 7.6 V
VHO = VHB = 7.6 V
2.2
3.3
2.9
65
A
2.56
3.32
100
V
HB – SW = 7.6 V
µA
LO GATE DRIVER
VOHL
VOLL
LO High-state Voltage Drop
ILO = –100 mA, VOHL = VCC-VLO
ILO = 100 mA, VOLL = VLO
C-load = 1000 pF(2)
C-load = 1000 pF(2)
VLO = 0 V
0.17
0.1
6
0.27
0.2
V
V
LO Low-state Voltage Drop
LO rise time
ns
ns
A
LO fall time
5
IOHL
Peak LO source current
Peak LO sink current
2.5
3.3
IOLL
VLO = 7.6 V
A
THERMAL
TSD
Thermal shutdown
Temperature rising
165
25
°C
°C
Thermal shutdown hysteresis
(2) High and low reference are 80% and 20% of the pulse amplitude, respectively.
6.7 Switching Characteristics
over operating free-air temperature range (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
72
MAX
UNIT
ns
TDLH
TDHL
LO fall to HO rise delay
HO fall to LO rise delay
No load
71
ns
8
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6.8 Typical Characteristics
Figure 1. HO Peak Driver Current vs Output Voltage
Figure 2. LO Peak Driver Current vs Output Voltage
Figure 4. Driver Dead Time vs Temperature
Figure 6. Switching Frequency vs RT
Figure 3. Driver Dead Time vs VVCC
Figure 5. Forced HO Off-time vs Temperature
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Typical Characteristics (continued)
Figure 7. VVCC vs IVCC
Figure 8. VVCC vs VVIN
Figure 9. VCS(TH) vs Temperature
Figure 10. VREF vs Temperature
Figure 12. Error Amp Gain and Phase vs Frequency
Figure 11. VVCC vs Temperature
10
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Typical Characteristics (continued)
Figure 13. VCM vs IOUT
Figure 14. VCM vs VCSG-CS
7 Detailed Description
7.1 Overview
The LM5117 high voltage switching controller features all of the functions necessary to implement an efficient
high voltage buck regulator that operates over a very wide input voltage range. This easy to use controller
integrates high-side and low-side NMOS drivers. The regulator control method is based upon peak current mode
control utilizing an emulated current ramp. Peak current mode control provides inherent line feed-forward, cycle-
by-cycle current limiting and ease of loop compensation. The use of an emulated control ramp reduces noise
sensitivity of the PWM circuit, allowing reliable processing of the very small duty cycles necessary in high input
voltage applications.
The switching frequency is user programmable up to 750 kHz. The RT pin allows the switching frequency to be
programmed by a single resistor or synchronized to an external clock. Fault protection features include cycle-by-
cycle and hiccup mode current limiting, thermal shutdown and remote shutdown capability by pulling down UVLO
pin. The UVLO input enables the regulator when the input voltage reaches a user selected threshold and
provides a very low quiescent shutdown current when pulled low. A unique analog telemetry feature provides
averaged output current information, allowing various applications that need either a current monitor or current
control. The functional block diagram and typical application circuit of the LM5117 are shown in Functional Block
Diagram.
The device is available in a HTSSOP-20 (6.5 mm x 4.4 mm) package, as well as a WQFN-24 (4 mm × 4 mm)
package which features an exposed pad to aid in thermal dissipation.
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7.2 Functional Block Diagram
12
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7.3 Feature Description
7.3.1 High Voltage Start-up Regulator and VCC Disable
The LM5117 contains an internal high voltage bias regulator that provides the VCC bias supply for the PWM
controller and NMOS gate drivers. The VIN pin can be connected to an input voltage source as high as 65 V.
The output of the VCC regulator is set to 7.6V. When the input voltage is below the VCC set-point level, the VCC
output tracks the VIN with a small dropout voltage. The output of the VCC regulator is current limited at 30mA
minimum.
Upon power-up, the regulator sources current into the capacitor connected to the VCC pin. The recommended
capacitance range for the pin VCC is 0.47 µF to 10 µF. When the VCC pin voltage exceeds the VCC UV
threshold and the UVLO pin is greater than UVLO threshold, the HO and LO drivers are enabled and a soft-start
sequence begins. The HO and LO drivers remain enabled until either the VCC pin voltage falls below VCC UV
threshold, the UVLO pin voltage falls below UVLO threshold, hiccup mode is activated or the die temperature
exceeds the thermal shutdown threshold. Enabling/Disabling the IC by controlling UVLO is recommended in most
of cases.
An output voltage derived bias supply can be applied to the VCC pin to reduce the controller power dissipation at
higher input voltage. The VCCDIS input can be used to disable the internal VCC regulator when external biasing
is supplied. The externally supplied bias should be coupled to the VCC pin through a diode, preferably a
Schottky diode. If the VCCDIS pin voltage exceeds the VCCDIS threshold, the internal VCC regulator is disabled.
VCCDIS has a 500-kΩ internal pull-down resistor to ground for normal operation with no external bias.
The VCC regulator series pass transistor includes a diode between VCC (Anode) and VIN (Cathode) that should
not be forward biased in normal operation. If the voltage of the external bias supply is greater than the VIN pin
voltage, an external blocking diode is required from the input power supply to the VIN pin to prevent the external
bias supply from passing current to the input supply through VCC.
V
IN
VIN
LM5117
External
VCC Supply
VCC
Figure 15. VIN Configuration for VVIN < VVCC
For VOUT between 6 V and 14.5 V, the output can be connected directly to VCC through a diode.
V
OUT
VCC
LM5117
VCCDIS resistor divider is
required when external VCC
supplying voltage is smaller
than 8.5V
VCCDIS
Figure 16. External VCC Supply for 6 V < VOUT< 14.5 V
For VOUT < 6 V, a bias winding on the output inductor can be added to generate the external VCC supply voltage.
VCC
LM5117
VCCDIS
V
OUT
SW
VCCDIS resistor divider is
required when external VCC
supplying voltage is smaller
than 8.5V
Figure 17. External VCC Supply for VOUT < 6 V
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Feature Description (continued)
For 14.5 V <VOUT, the external supply voltage can be regulated by using a series Zener diode from the output to
VCC.
V
OUT
R
1
VCC
Zener
R1 is required to limit maximum reverse
zener current 30 kW minimum resistive
loss at VCC guarantees minimum reverse
zener current
30 kW
LM5117
Figure 18. External VCC Supply for 14.5 V < VOUT
In high input voltage applications, extra care should be taken to ensure the VIN pin does not exceed the absolute
maximum voltage rating of 75V. During line or load transients, voltage ringing on the VIN that exceeds the
Absolute Maximum Rating can damage the IC. Both careful PC board layout and the use of quality bypass
capacitors located close to the VIN and AGND pin are essential. Adding an R-C filter (RVIN, CVIN) on VIN is
optional and helps to prevent faulty operation caused by poor PC board layout and high frequency switching
noise injection. The recommended capacitance and resistance range are 0.1 µF to 10 µF and 1 Ω to 10 Ω.
7.3.2 UVLO
The LM5117 contains a dual level UVLO (under-voltage lockout) circuit. When the UVLO is less than 0.4 V, the
LM5117 is in shutdown mode. The shutdown comparator provides 100 mV of hysteresis to avoid chatter during
transitions. When the UVLO pin voltage is greater than 0.4 V but less than 1.25 V, the controller is in standby
mode. In the standby mode, the VCC bias regulator is active but the HO and LO drivers are disabled and the SS
pin is held low. This feature allows the UVLO pin to be used as a remote shutdown function by pulling the UVLO
pin down below 0.4 V with an external open collector or open drain device. When the VCC pin exceeds its under-
voltage lockout threshold and the UVLO pin voltage is greater than 1.25 V, the HO and LO drivers are enabled
and normal operation begins.
UVLO Hysteresis
V
IN
Current
LM5117
UVLO
Threshold
R
UV2
-
+
UVLO
STANDBY
UVLO
Shutdown
Threshold
C
FT
R
UV1
-
+
SHUTDOWN
Figure 19. UVLO Configuration
The UVLO pin should not be left floating. An external UVLO set-point voltage divider from the VIN to AGND is
used to set the minimum input operating voltage of the regulator. The divider must be designed such that the
voltage at the UVLO pin is greater than 1.25 V and never exceeds 15 V when the input voltage is in the desired
operating range. If necessary, the UVLO pin can be clamped with a Zener diode.
UVLO hysteresis is accomplished with an internal 20μA current source that is switched on or off into the
impedance of the UVLO set-point divider. When the UVLO pin voltage exceeds the 1.25 V threshold, the current
source is enabled to quickly raise the voltage at the UVLO pin. When the UVLO pin voltage falls below the 1.25
V threshold, the current source is disabled causing the voltage at the UVLO pin to quickly fall. The use of a CFT
capacitor in parallel with RUV1 helps to minimize switching noise injection into UVLO pin, but it may slow down
the falling speed of the UVLO pin when the 20 μA current source is disabled. The recommended range for CFT is
10 pF to 220 pF.
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Feature Description (continued)
The values of RUV1 and RUV2 can be determined from the following equations:
VHYS
[5]
RUV2
=
20 µA
(1)
1.25V x RUV2
[5]
RUV1
=
VIN(STARTUP) - 1.25V
where
•
VHYS is the desired UVLO hysteresis and VIN(STARTUP) is the desired start-up voltage of the regulator during turn-
on (2)
7.3.3 Oscillator and Sync Capability
The LM5117 switching frequency is programmed by a single external resistor connected between the RT pin and
the AGND pin. The resistor should be located very close to the device and connected directly to the RT and
AGND pins. To set a desired switching frequency (ƒSW), the resistor value can be calculated from the following
equation:
5.2 x 109
fSW
- 948 [5]
RT =
(3)
The RT pin can be used to synchronize the internal oscillator to an external clock. The internal oscillator can be
synchronized by AC coupling a positive edge into the RT pin. The voltage at the RT pin is nominally 1.25 V and
the voltage at the RT pin must exceed the RT Sync Positive Threshold to trip the internal synchronization pulse
detector. A 5 V amplitude pulse signal coupled through a 100-pF capacitor is a good starting point. The
frequency of the external synchronization pulse is recommended to be within ±10% of the frequency
programmed by the RT resistor but will operate to +100/-40% of the programmed frequency. Care should be
taken to guarantee that the RT pin voltage does not go below –0.3 V at the falling edge of the external pulse.
This may limit the duty cycle of external synchronization pulse.
The RT resistor is always required, whether the oscillator is free running or externally synchronized.
7.3.4 Ramp Generator and Emulated Current Sense
The ramp signal used in the pulse width modulator for traditional current mode control is typically derived directly
from the high-side switch current. This switch current corresponds to the positive slope portion of the inductor
current. Using this signal for the PWM ramp simplifies the control loop transfer function to a single pole response
and provides inherent input voltage feed-forward compensation.
The disadvantage of using the high-side switch current signal for PWM control is the large leading edge spike
due to circuit parasitics that must be filtered or blanked. Minimum achievable pulse width is limited by the
filtering, blanking time and propagation delay with a high-side current sensing scheme.
In the applications where the input voltage may be relatively large in comparison to the output voltage, controlling
small pulse widths and duty cycles are necessary for regulation. The LM5117 utilizes a unique ramp generator
which does not actually measure the high-side switch current but rather reconstructs the signal. Representing or
emulating the inductor current provides a ramp signal to the PWM comparator that is free of leading edge spikes
and measurement or filtering delays, while maintaining the advantages of traditional peak current mode control.
The current reconstruction is comprised of two elements: a sample-and-hold DC level and the emulated inductor
current ramp as shown in Figure 20. The sample-and-hold DC level is derived from a measurement of the
recirculating current flowing through the current sense resistor. The voltage across the sense resistor is sampled
and held just prior to the onset of the next conduction interval of the high-side switch. The current sense amplifier
with a gain of 10 and sample-and-hold circuit provide the DC level of the reconstructed current signal as shown
in Figure 21.
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Feature Description (continued)
Additional Slope
V
x t
IN
ON
x C
RAMP
=
PK
R
RAMP
RAMP
I
x R x 10
S
LO
Sample and Hold
DC Level
t
ON
Figure 20. Composition of Emulated Current Sense Signal
CS
10 x VCS(TH)
Current Sense
Amplifier
-
-
+
AS=10
R
S
I
L
+
Current Limit
Comparator
CSG
HO_ENABLE
LM5117
RAMP
SW
R
RAMP
C
RAMP
Figure 21. RAMP Generator and Current Limit Circuit
The positive slope inductor current ramp is emulated by CRAMP connected between RAMP and AGND and RRAMP
connected between SW and RAMP. RRAMP should not be connected to VIN directly because the RAMP pin
absolute maximum voltage rating could be exceeded under high input voltage conditions. CRAMP is discharged by
an internal switch during the off-time and must be fully discharged during the minimum off-time. This limits the
ramp capacitor to be less than 2 nF. A good quality, thermally stable ceramic capacitor is recommended for
CRAMP
.
The selection of RRAMP and CRAMP can be simplified by adopting a K factor, which is defined as:
LO
K =
RRAMP x CRAMP x RS x AS
where
•
AS is the current sense amplifier gain which is normally 10
(4)
By choosing 1 as the K factor, the regulator removes any error after one switching cycle and the design
procedure is simplified. See Application and Implementation for detailed information.
7.3.5 Error Amplifier and PWM Comparator
The internal high-gain error amplifier generates an error signal proportional to the difference between the FB pin
voltage and the internal precision 0.8-V reference. The output of error amplifier is connected to the COMP pin
allowing the user to provide Type 2 loop compensation components, RCOMP, CCOMP and optional CHF
.
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Feature Description (continued)
V
OUT
REF
LM5117
PWM
R
FB2
Comparator
+
-
-
+
-
+
FB
Error
Amplifier
R
COMP
C
COMP
COMP
RAMP Generator
Output
R
FB1
(optional)
C
HF
Type 2 Compensation
Components
Figure 22. Feedback Configuration and PWM Comparator
RCOMP, CCOMP and CHF configure the error amplifier gain and phase characteristics to achieve a stable voltage
loop gain. This network creates a pole at DC (FP1), a mid-band zero (FZ) for phase boost, and a high frequency
pole (FP2). The recommended range of RCOMP is 2 kΩ to 40 kΩ. See Application and Implementation for detailed
information.
FP1 = 0
[Hz]
(5)
1
FZ =
[Hz]
2p x RCOMP x CCOMP
(6)
1
[Hz]
FP2
=
CCOMP x CHF
≈
x
’
2p x RCOMP
CCOMP + CHF
«
◊
(7)
The PWM comparator compares the emulated current sense signal from Ramp Generator to the voltage at the
COMP pin through a 1.2-V internal voltage drop and terminates the present cycle when the emulated current
sense signal is greater than VCOMP – 1.2 V.
7.3.6 Soft-Start
The soft-start feature allows the regulator to gradually reach the steady state operating point, thus reducing
startup stresses and surges. The LM5117 regulates the FB pin to the SS pin voltage or the internal 0.8-V
reference, whichever is lower. The internal 10-µA soft-start current source gradually increases the voltage on an
external soft-start capacitor connected to the SS pin. This results in a gradual rise of the output voltage. Soft-start
time (tss) can be calculated from the following equation:
CSS x 0.8V
[sec]
tSS
=
10 µA
(8)
The LM5117 can track the output of a master power supply during soft-start by connecting a voltage divider from
the output of master power supply to the SS pin. At the beginning of the soft-start sequence, VSS should be
allowed to go below 25 mV by the internal SS pull-down switch. During soft-start period, when SS pin voltage is
less than 0.8V, the LM5117 forces diode emulation for startup into a pre-biased load. If the tracking feature is
desired, connect the DEMB pin to GND or leave the pin floating.
7.3.7 Cycle-by-Cycle Current Limit
The LM5117 contains a current limit monitoring scheme to protect the regulator from possible over-current
conditions as shown in Figure 21. If the emulated ramp signal exceeds 1.2 V, the present cycle is terminated. For
the case where the switch current overshoots when the inductor is saturated or the output is shorted to ground,
the sample-and-hold circuit detects the excess recirculating current before the high-side NMOS driver is turned
on again. The high-side NMOS driver is disabled and will skip pulses until the current has decayed below the
current limit threshold. This approach prevents current runaway conditions since the inductor current is forced to
decay to a controlled level following any current overshoot.
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Feature Description (continued)
Maximum peak inductor current can be calculated as:
VCS(TH)
VOUT
[A]
IL(MAX)_PK
=
+ IPP -
RS
fSW x AS x RS x RRAMP x CRAMP
(9)
IPP
2
IL(MAX)_AVE = IL(MAX)_PK
-
[A]
where
•
IPP represents inductor peak to peak ripple current in Figure 23, and is defined as:
(10)
(11)
VOUT
VIN
VOUT
LO x fSW
≈
«
’
÷
◊
x 1 -
[A]
IPP
=
∆
IPP
IOUT
1
fSW
T=
0
Figure 23. Inductor Current
During an output short condition, the worst case peak inductor current is limited to:
VCS(TH) VIN(MAX) x tON(MIN)
+
[A]
ILIM_PK
=
RS
LO
where
•
tON(MIN) is the minimum HO on-time
(12)
In most cases, especially if the output voltage is relatively high, it is recommended that a soft-saturating inductor
such as a powder core device is used. If a sharp-saturating inductor is used, the inductor saturation level must
be above ILIM_PK. The temperatures of the NMOS devices, RS and inductor should be checked under this output
short condition.
7.3.8 Hiccup Mode Current Limiting
To further protect the regulator during prolonged current limit conditions, LM5117 provides a hiccup mode current
limit. An internal hiccup mode fault timer counts the PWM clock cycles during which cycle-by-cycle current
limiting occurs. When the hiccup mode fault timer detects 256 consecutive cycles of current limiting, an internal
restart timer forces the controller to enter a low power dissipation standby mode and starts sourcing 10 μA of
current into the RES pin capacitor CRES. In this standby mode, HO and LO outputs are disabled and the soft-start
capacitor CSS is discharged.
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Feature Description (continued)
CRES is connected from RES pin to AGND and determines the time (tRES) in which the LM5117 remains in the
standby before automatically restarting. When the RES pin voltage exceeds the 1.25-V RES threshold, RES
capacitor is discharged and a soft-start sequence begins. tRES can be calculated from the following equation:
CRES x 1.25V
[sec]
tRES
=
10 mA
(13)
Current Limit
Detected
1.25V RES Threshold
I
= 10 µA
RES
0V
RES
SS
I
= 10 µA
SS
0.8V REF
HO
LO
Current Limit
t
t
SS
RES
persists during 256
consecutive cycles
Figure 24. Hiccup Mode Current Limit Timing Diagram
STANDBY
LM5117
RES
Current
HICCUP MODE
FAULT TIMER
256 CYCLES
HICCUP
RESTART
TIMER
RES
C
RES
Current Limit
Comparator
-
+
Figure 25. Hiccup Mode Current Limit Circuit
The RES pin can also be configured for latch-off mode current limiting or non-hiccup mode cycle-by-cycle current
limiting. If the RES pin is tied to VCC or a voltage greater than the RES threshold at initial power-on, the restart
timer is disabled and the regulator operates with non-hiccup mode cycle-by-cycle current limit. If the RES pin is
tied to GND, the regulator enters into the standby mode after 256 consecutive cycles of current limiting and then
never restarts until UVLO shutdown is cycled. The restart timer is configured during initial power-on when UVLO
is above the UVLO threshold and VCC is above the VCC UV threshold.
RES
RES
RES
C
RES
LM5117
LM5117
LM5117
VCC
VCC
(a) Hiccup Mode
Current Limit
(b) Latch-off Mode
Current Limit
(c) Cycle-by-cycle
Current Limit
Figure 26. RES Configurations
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Feature Description (continued)
7.3.9 HO and LO Drivers
The LM5117 contains high current NMOS drivers and an associated high-side level shifter to drive the external
high-side NMOS device. This high-side gate driver works in conjunction with an external diode DHB, and
bootstrap capacitor CHB. A 0.1-μF or larger ceramic capacitor, connected with short traces between the HB and
SW pin, is recommended. During the off-time of the high-side NMOS driver, the SW pin voltage is approximately
0V and the CHB is charged from VCC through the DHB. When operating with a high PWM duty cycle, the high-
side NMOS device is forced off each cycle for 320 ns to ensure that CHB is recharged.
The LO and HO outputs are controlled with an adaptive dead-time methodology which insures that both outputs
are never enabled at the same time. When the controller commands HO to be enabled, the adaptive dead-time
logic first disables LO and waits for the LO voltage to drop. HO is then enabled after a small delay (LO Fall to HO
Rise Delay). Similarly, the LO turn-on is delayed until the HO voltage has discharged. LO is then enabled after a
small delay (HO Fall to LO Rise Delay). This technique insures adequate dead-time for any size NMOS device,
especially when VCC is supplied by a higher external voltage source. The adaptive dead-time circuitry monitors
the voltages of HO and LO outputs and insures the dead-time between the HO and LO outputs. Adding a gate
resister, RGH or RGL, may decrease the effective dead-time.
Care should be exercised in selecting an output NMOS device with the appropriate threshold voltage, especially
if VCC is supplied by an external bias supply voltage below the VCC regulation level. During startup at low input
voltages, the low-side NMOS device gate plateau voltage should be lower than the VCC under-voltage lockout
threshold. Otherwise, there may be insufficient VCC voltage to completely enhance the NMOS device as the
VCC under-voltage lockout is released during startup. If the high-side NMOS drive voltage is lower than the high-
side NMOS device gate plateau voltage during startup, the regulator may not start or it may hang up momentarily
in a high power dissipation state. This condition can be addressed by selecting an NMOS device with a lower
threshold voltage. This situation can be avoided if the minimum input voltage programmed by the UVLO resistor
is above the VCC regulation level.
7.3.10 Current Monitor
The LM5117 provides average output current information, enabling various applications requiring monitoring or
control of the output current.
Current Sense
Amplifier Output
LM5117
Current Monitor
Amplifier
R
CM
CM
CONDITIONER
A
M
= 2
C
CM
40 kW
Figure 27. Current Monitor
The average of CM output can be calculated by:
= I +I ´R ´ A
V
V
[ ]
(
)
CM_ AVE
PEAK
VALLEY
S
S
(14)
The current monitor output is only valid in continuous conduction operation. The current monitor has a limited
bandwidth of approximately one tenth of fSW. Adding an R-C filter, RCM and CCM, on the output of current monitor
with the cut off frequency below one tenth of fSW is recommended to attenuate sampling noise.
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Feature Description (continued)
7.3.11 Maximum Duty Cycle
When operating with a high PWM duty cycle, the high-side NMOS device is forced off each cycle for 320ns to
ensure that CHB is recharged and to allow time to sample and hold the current in the low-side NMOS FET. This
forced off-time limits the maximum duty cycle of the controller. When designing a regulator with high switching
frequency and high duty cycle requirements, a check should be made of the required maximum duty cycle
against the graph shown in Figure 28. The actual maximum duty cycle varies with the switching frequency as
follows:
Figure 28. Maximum Duty Cycle vs Switching Frequency
7.3.12 Thermal Protection
Internal thermal shutdown circuitry is provided to protect the controller in the event the maximum junction
temperature is exceeded. When activated, typically at 165°C, the controller is forced into a low power shutdown
mode, disabling the output drivers and the VCC regulator. This feature is designed to prevent overheating and
destroying the device.
7.4 Device Functional Modes
7.4.1 Diode Emulation
A fully synchronous buck regulator implemented with a freewheeling NMOS rather than a diode has the
capability to sink current from the output in certain conditions such as light load, over-voltage or pre-bias startup.
The LM5117 provides a diode emulation feature that can be enabled to prevent reverse current flow in the low-
side NMOS device. When configured for diode emulation, the low-side NMOS driver is disabled when SW pin
voltage is greater than -5mV during the off-time of the high-side NMOS driver, preventing reverse current flow.
A benefit of the diode emulation is lower power loss at no load or light load conditions. The negative effect of
diode emulation is degraded light load transient response.
The diode emulation feature is configured with the DEMB pin. To enable diode emulation, connect the DEMB pin
to GND or leave the pin floating. If continuous conduction operation is desired, the DEMB pin should be tied to a
voltage greater than 3 V and may be connected to VCC. The LM5117 forces the regulator to operate in diode
emulation mode when SS pin voltage is less than the internal 0.8-V reference, allowing for startup into a pre-
biased load with the continuous conduction configuration.
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8 Application and Implementation
NOTE
Information in the following applications sections is not part of the TI component
specification, and TI does not warrant its accuracy or completeness. TI’s customers are
responsible for determining suitability of components for their purposes. Customers should
validate and test their design implementation to confirm system functionality.
8.1 Application Information
The LM5117 is a step-down dc-dc controller. The device is typically used to convert a higher dc-dc voltage to a
lower dc voltage. Use the following design procedure to select component values. Alternately, use the
WEBENCH® software to generate a complete design. The WEBENCH software uses an iterative design
procedure and assesses a comprehensive database of components when generating a design.
8.2 Typical Applications
Figure 29. 12 V, 9 A Typical Application Schematic
8.3 Detailed Design Procedure
8.3.1 Feedback Compensation
Open loop response of the regulator is defined as the product of modulator transfer function and feedback
transfer function. When plotted on a dB scale, the open loop gain is shown as the sum of modulator gain and
feedback gain.
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Detailed Design Procedure (continued)
The modulator transfer function includes a power stage transfer function with an embedded current loop and can
be simplified as one pole and one zero system as shown in Equation 15.
s
1 +
^
w
VOUT
Z_ESR
= AM
x
^
s
VCOMP
≈
’
◊
1+
w
«
P_LF
(15)
RLOAD
RS x AS
Where AM (Modulator DC gain) =
,
1
,
w
Z_ESR (ESR zero) =
RESR x COUT
1
w
P_LF (Load pole) =
RLOAD x COUT
If the ESR of COUT (RESR) is very small, the modulator transfer function can be further simplified to a one pole
system and the voltage loop can be closed with only two loop compensation components, RCOMP and CCOMP
,
leaving a single pole response at the crossover frequency. A single pole response at the crossover frequency
yields a very stable loop with 90 degrees of phase margin.
The feedback transfer function includes the feedback resistor divider and loop compensation of the error
amplifier. RCOMP, CCOMP and optional CHF configure the error amplifier gain and phase characteristics and create
a pole at origin, a low frequency zero and a high frequency pole. This is shown mathematically in Equation 16.
s
1 +
^
w
VCOMP
Z_EA
-
= AFB
x
s
P_EA
^
VOUT
s x (1+
)
w
(16)
1
,
Where AFB (Feedback DC gain) =
wZ_EA (Low frequency zero) =
RFB2 x (CCOMP + CHF
)
1
RCOMP x CCOMP
,
1
wP_EA (High frequency pole) =
RCOMP x CHF
The pole at the origin minimizes output steady state error. The low frequency zero should be placed to cancel the
load pole of the modulator. The high frequency pole can be used to cancel the zero created by the output
capacitor ESR or to decrease noise susceptibility of the error amplifier. By placing the low frequency zero an
order of magnitude less than the crossover frequency, the maximum amount of phase boost can be achieved at
the crossover frequency. The high frequency pole should be placed well beyond the crossover frequency since
the addition of CHF adds a pole in the feedback transfer function.
The crossover frequency (loop bandwidth) is usually selected between one twentieth and one fifth of the fSW. In a
simplified formula, the crossover frequency can be defined as:
RCOMP
[Hz]
fCROSS
=
2 x ' x RS x RFB2 x AS x COUT
(17)
For higher crossover frequency, RCOMP can be increased, while proportionally decreasing CCOMP. Conversely,
decreasing RCOMP while proportionally increasing CCOMP, results in lower bandwidth while keeping the same zero
frequency in the feedback transfer function.
The sampled gain inductor pole is inversely proportional to the K factor, which is defined as:
fSW
wp_HF
=
K - 0.5
(18)
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Detailed Design Procedure (continued)
The maximum achievable loop bandwidth, in fact, is limited by this sampled gain inductor pole. In traditional
current mode control, the maximum achievable loop bandwidth varies with input voltage. With the LM5117’s
unique slope compensation scheme, the sampled gain inductor pole is independent of changes to the input
voltage. This frees the user from additional concerns in wide varying input range applications and is an
advantage of the LM5117.
If the sampled gain inductor pole or the ESR zero is close to the crossover frequency, it is recommended that the
comprehensive formulas in Table 1 be used and the stability should be checked by a network analyzer. The
modulator transfer function can be measured and the feedback transfer function can be configured for the
desired open loop transfer function. If a network analyzer is not available, step load transient tests can be
performed to verify acceptable performance. The step load goal is minimum overshoot/undershoot with a
damped response.
8.3.2 Sub-Harmonic Oscillation
Peak current mode regulators can exhibit unstable behavior when operating above 50% duty cycle. This
behavior is known as sub-harmonic oscillation and is characterized by alternating wide and narrow pulses at the
SW pin. Sub-harmonic oscillation can be prevented by adding an additional voltage ramp (slope compensation)
on top of the sensed inductor current shown in Figure 20. By choosing K≥1, the regulator will not be subject to
sub-harmonic oscillation caused by a varying input voltage.
In time-domain analysis, the steady-state inductor current starts and ends at the same value during one clock
cycle. If the magnitude of the end-of-cycle current error, dI1, caused by an initial perturbation, dI0, is less than the
magnitude of dI0 or dI1/dI0 > -1, the perturbation naturally disappears after a few cycles. When dI1/dI0 < -1, the
initial perturbation does not disappear, resulting in sub-harmonic oscillation in steady-state operation.
Steady-State
Inductor
Current
dI
0
t
ON
dI
1
Inductor Current with
Initial Perturbation
Figure 30. Effect of Initial Perturbation when dl1/dl0 < -1
dI1/dI0 can be calculated by:
dl1
dl0
1
K
= 1 -
(19)
The relationship between dI1/dI0 and K factor is illustrated graphically in Figure 31.
Figure 31. dl1/dl0 vs K Factor
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Detailed Design Procedure (continued)
The minimum value of K is 0.5. When K<0.5, the amplitude of dI1 is greater than the amplitude of dI0 and any
initial perturbation results in sub-harmonic oscillation. If K=1, any initial perturbation will be removed in one
switching cycle. This is known as one-cycle damping. When -1<dl1/dl0<0, any initial perturbation will be under-
damped. Any perturbation will be over-damped when 0<dl1/dl0<1.
In the frequency-domain, Q, the quality factor of the sampling gain term in the modulator transfer function, is
used to predict the tendency for sub-harmonic oscillation, which is defined as:
1
Q =
p(K-0.5)
(20)
The relationship between Q and K factor is illustrated graphically in Figure 32.
Figure 32. Sampling gain Q vs K Factor
The minimum value of K is 0.5 again. This is the same as time domain analysis result. When K<0.5, the regulator
is unstable. High gain peaking at 0.5 results in sub-harmonic oscillation at FSW/2. When K=1, one-cycle damping
is realized. Q is equal to 0.673 at this point. A higher K factor may introduce additional phase shift by moving the
sampled gain inductor pole closer to the crossover frequency, but will help reduce noise sensitivity in the current
loop. The maximum allowable value of K factor can be calculated by the Maximum Crossover Frequency
equation in Table 1.
8.3.3 Design Requirements
DESIGN PARAMETER
Output voltage
EXAMPLE VALUE
12 V
9 A
Full load current, IOUT
Minimum input voltage, VIN(MIN)
Maximum input voltage, VIN(MAX)
Switching frequency, ƒSW
Diode emulation
15 V
55 V
230 kHz
yes
External VCC supply
yes
8.3.4 Timing Resistor RT
Generally, higher frequency applications are smaller but have higher losses. Operation at 230 kHz was selected
for this example as a reasonable compromise between small size and high efficiency. The value of RT for 230
kHz switching frequency can be calculated from Equation 3 as follows:
5.2 x 109
230 x 103
- 948 = 21.7 kW
RT =
(21)
A standard value of 22.1 kΩ was chosen for RT.
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8.3.5 Output Inductor LO
The maximum inductor ripple current occurs at the maximum input voltage. Typically, 20% to 40% of the full load
current is a good compromise between core loss and copper loss of the inductor. Higher ripple current allows for
a smaller inductor size, but places more of a burden on the output capacitor to smooth the ripple voltage on the
output. For this example, a ripple current of 40% of 9 A was chosen. Knowing the switching frequency, maximum
ripple current, maximum input voltage and the nominal output voltage, the inductor value can be calculated as
follows:
æ
ö
÷
V
V
OUT
æ
ö
÷
ø
12V
12V
55V
OUT
ç
L
=
´ 1-
=
´ 1-
= 11.3mH
ç
O
I
´ f
ç
è
V
÷
9A ´0.4´ 230kHz
è
PP(MAX)
SW
IN MAX
(
)
ø
(22)
The closest standard value of 10 μH was chosen for LO. Using the value of 10 μH for LO, calculate IPP again.
This step is necessary if the chosen value of LO differs significantly from the calculated value.
From Equation 11,
12V
55V
≈
«
’
÷
◊
12V
x
1 -
IPP(MAX)
=
= 4.1A
∆
10 mH x 230 kHz
(23)
At the minimum input voltage, this value is 1.04 A.
8.3.6 Diode Emulation Function
The DEMB pin is left floating since this example uses diode emulation to reduce the power loss under no load or
light load conditions.
8.3.7 Current Sense Resistor RS
The performance of the converter will vary depending on the K value. For this example, K = 1 was chosen to
control sub-harmonic oscillation and achieve one-cycle damping. The maximum output current capability
(IOUT(MAX)) should be 20~50% higher than the required output current, to account for tolerances and ripple
current. For this example, 130% of 9 A was chosen. The current sense resistor value can be calculated from
Equation 9 and Equation 10 as follows:
VCS(TH)
[W]
RS
=
VOUT x K IPP
_
IOUT(MAX)
+
2
fSW x LO
(24)
(25)
0.12V
12 x 1
230 kHz x 10 µH
RS
=
= 7.3 mW
1.04A
2
_
9A x 1.3 +
A value of 7.41 mΩ was realized for RS by placing an additional 0.1-Ω sense resistor in parallel with 8 mΩ. The
sense resistor must be rated to handle the power dissipation at maximum input voltage when current flows
through the low-side NMOS for the majority of the PWM cycle. The maximum power dissipation of RS can be
calculated as:
VOUT
≈
«
’
÷
◊
IOUT2 x RS
x
PRS = 1 -
[W]
∆
VIN(MAX)
(26)
12V
55V
2
≈
’
PRS = 1 -
x 9A x 7.41 mW = 0.47W
«
◊
(27)
The worst case peak inductor current under the output short condition can be calculated from Equation 12 as
follows:
0.12V
7.41 mW
55V x 100 ns
+
= 16.7A
ILIM_PK
=
10 mH
where
•
tON(MIN) is normally 100ns
(28)
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8.3.8 Current Sense Filter RCS and CCS
The LM5117 itself is not affected by the large leading edge spike because it samples valley current just prior to
the onset of the high-side switch. A current sense filter is used to minimize a noise injection from any external
noise sources. In general, a current sense filter is not necessary. In this example, a current sense filter is not
used
Adding RCS resistor changes the current sense amplifier gain which is defined as AS=10 k / (1 k+RCS). A small
value of RCS resistor below 100 Ω is recommended to minimize the gain change which is caused by the
temperature coefficient difference between internal and external resistors.
8.3.9 Ramp Resistor RRAMP and Ramp Capacitor CRAMP
The positive slope of the inductor current ramp signal is emulated by RRAMP and CRAMP. For this example, the
value of CRAMP was set at the standard capacitor value of 820 pF. With the inductor, sense resistor and the K
factor selected, the value of RRAMP can be calculated from Equation 4 as follows:
LO
[W]
RRAMP
=
K x CRAMP x RS x AS
(29)
10 mH
= 165 kW
RRAMP
=
1 x 820 pF x 7.41 mW x 10
(30)
The standard value of 165 kΩ was selected for RRAMP
.
8.3.10 UVLO Divider RUV2, RUV1 and CFT
The desired startup voltage and the hysteresis are set by the voltage divider RUV1 and RUV2. Capacitor CFT
provides filtering for the divider. For this design, the startup voltage was set to 14 V, 1 V below VIN(MIN). VHYS was
set to 2 V. The value of RUV1, RUV2 can be calculated from Equation 1 and Equation 2 as follows:
2V
20 µA
RUV2
=
= 100 kW
(31)
1.25V x 100 kW
14V -1.25V
RUV1
=
= 9.8 kW
(32)
The standard value of 100 kΩ was selected for RUV2. RUV1 was selected to be 9.76 kΩ. A value of 47 pF was
chosen for CFT.
8.3.11 VCC Disable and External VCC Supply
The 12-V output voltage allows the external VCC supply configuration as shown in Figure 16. In this example,
VCCDIS can be left floating since VOUT is higher than VCC regulator set-point level.
8.3.12 Power Switches QH and QL
Selection of the power NMOS devices is governed by the same trade-offs as switching frequency. Breaking
down the losses in the high-side and low-side NMOS devices is one way to compare the relative efficiencies of
different devices. Losses in the power NMOS devices can be broken down into conduction loss, gate charging
loss, and switching loss.
Conduction loss PDC is approximately:
PDC (High-Side) = D x (IOUT2 x RDS(ON) x 1.3)
[W]
(33)
PDC (Low-Side) = (1 œ D) x (IOUT2 x RDS(ON) x 1.3)
[W]
where
•
•
D is the duty cycle
the factor of 1.3 accounts for the increase in the NMOS device on-resistance due to heating
(34)
Alternatively, the factor of 1.3 can be eliminated and the high temperature on-resistance of the NMOS device can
be estimated using the RDS(ON) vs Temperature curves in the MOSFET datasheet.
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Gate charging loss (PGC) results from the current driving the gate capacitance of the power NMOS devices and is
approximated as:
PGC = n x VVCC x Qg x fSW [W]
(35)
Qg refers to the total gate charge of an individual NMOS device, and ‘n’ is the number of NMOS devices. Gate
charge loss differs from conduction and switching losses in that the actual dissipation occurs in the controller IC.
Switching loss (PSW) occurs during the brief transition period as the high-side NMOS device turns on and off.
During the transition period both current and voltage are present in the channel of the NMOS device. The
switching loss can be approximated as:
PSW = 0.5 x VIN x IOUT x (tR + tF) x fSW [W]
(36)
tR and tF are the rise and fall times of the high-side NMOS device. The rise and fall times are usually mentioned
in the MOSFET datasheet or can be empirically observed with an oscilloscope. Switching loss is calculated for
the high-side NMOS device only. Switching loss in the low-side NMOS device is negligible because the body
diode of the low-side NMOS device turns on before and after the low-side NMOS device switches. For this
example, the maximum drain-to-source voltage applied to either NMOS device is 55 V. The selected NMOS
devices must be able to withstand 55 V plus any ringing from drain to source and must be able to handle at least
the VCC voltage plus any ringing from gate to source.
8.3.13 Snubber Components RSNB and CSNB
A resistor-capacitor snubber network across the low-side NMOS device reduces ringing and spikes at the
switching node. Excessive ringing and spikes can cause erratic operation and can couple noise to the output
voltage. Selecting the values for the snubber is best accomplished through empirical methods. First, make sure
the lead lengths for the snubber connections are very short. Start with a resistor value between 5 and 50 Ω.
Increasing the value of the snubber capacitor results in more damping, but higher snubber losses. Select a
minimum value for the snubber capacitor that provides adequate damping of the spikes on the switch waveform
at heavy load. A snubber may not be necessary with an optimized layout.
8.3.14 Bootstrap Capacitor CHB and Bootstrap Diode DHB
The bootstrap capacitor between the HB and SW pin supplies the gate current to charge the high-side NMOS
device gate during each cycle’s turn-on and also supplies recovery charge for the bootstrap diode. These current
peaks can be several amperes. The recommended value of the bootstrap capacitor is at least 0.1 μF. CHB should
be a good quality, low ESR, ceramic capacitor located at the pins of the IC to minimize potentially damaging
voltage transients caused by trace inductance. The absolute minimum value for the bootstrap capacitor is
calculated as:
Qg
CHB
[F]
í
DVHB
where
•
•
Qg is the high-side NMOS gate charge
ΔVHB is the tolerable voltage droop on CHB, which is typically less than 5% of VCC or 0.15 V conservatively
(37)
A value of 0.47 μF was selected for this design.
8.3.15 VCC Capacitor CVCC
The primary purpose of the VCC capacitor (CVCC) is to supply the peak transient currents of the LO driver and
bootstrap diode as well as provide stability for the VCC regulator. These peak currents can be several amperes.
The recommended value of CVCC should be no smaller than 0.47μF, and should be a good quality, low ESR,
ceramic capacitor. CVCC should be placed at the pins of the IC to minimize potentially damaging voltage
transients caused by trace inductance. A value of 1 μF was selected for this design.
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8.3.16 Output Capacitor CO
The output capacitors smooth the output voltage ripple caused by inductor ripple current and provide a source of
charge during transient loading conditions. For this design example, a 470-μF electrolytic capacitor with
maximum 20mΩ ESR was selected as the main output capacitor. The fundamental component of the output
ripple voltage with maximum ESR is approximated as:
2
1
≈
RESR +
’
÷
◊
2
[V]
DVOUT = IPP
x
∆
8 x fSW x COUT
«
(38)
2
1
≈
«
’
◊
DVOUT = 4.1 x 0.02W2 +
= 82 mV
∆
÷
8 x 230 kHz x 470 mF
(39)
Additional low ERS / ESL ceramic capacitors can be placed in parallel with the main output capacitor to further
reduce the output voltage ripple and spikes. In this example, two 22μF capacitors were added.
8.3.17 Input Capacitor CIN
The regulator input supply voltage typically has high source impedance at the switching frequency. Good quality
input capacitors are necessary to limit the ripple voltage at the VIN pin while supplying most of the switch current
during the on-time. When the high-side NMOS device turns on, the current into the device steps to the valley of
the inductor current waveform, ramps up to the peak value, and then drops to the zero at turnoff. The input
capacitor should be selected for RMS current rating and minimum ripple voltage. A good approximation for the
required ripple current rating necessary is IRMS > IOUT / 2.
In this example, seven 3.3μF ceramic capacitors were used. With ceramic capacitors, the input ripple voltage will
be triangular. The input ripple voltage can be approximated as:
IOUT
[V]
DVIN
DVIN
=
4 x
x CIN
fSW
(40)
(41)
9 A
= 0.42 V
=
4 x 230 kHz x 3.3 mF x 7
Capacitors connected in parallel should be evaluated for RMS current rating. The current will split between the
input capacitors based on the relative impedance of the capacitors at the switching frequency.
8.3.18 VIN Filter RVIN, CVIN
An R-C filter (RVIN, CVIN) on VIN is optional. The filter helps to prevent faults caused by high frequency switching
noise injection into the VIN pin. A 0.47-μF ceramic capacitor is used for CVIN in the example. RVIN is selected to
be 3.9 Ω.
8.3.19 Soft-Start Capacitor CSS
The capacitor at the SS pin (CSS) determines the soft-start time (tSS), which is the time for the output voltage to
reach the final regulated value. The tSS for a given CSS can be calculated from Equation 8 as follows:
0.1 µF x 0.8V
= 8 ms
tSS
=
10 µA
(42)
For this example, a value of 0.1 μF was chosen for a soft-start time of 8 ms.
8.3.20 Restart Capacitor CRES
The capacitor at the RES pin (CRES) determines tRES, which is the time the LM5117 remains off before a restart
attempt is made in hiccup mode current limiting. tRES for a given CRES can be calculated from Equation 13 as
follows:
0.47 µF x 1.25V
tRES
=
= 59 ms
10 µA
(43)
29
For this example, a value of 0.47 μF was chosen for a restart time of 59 ms.
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8.3.21 Output Voltage Divider RFB2 and RFB1
RFB1 and RFB2 set the output voltage level. The ratio of these resistors is calculated as:
RFB2 VOUT
=
- 1
0.8V
RFB1
(44)
The ratio between RCOMP and RFB2 determines the mid-band gain, AFB_MID. A larger value for RFB2 may require a
corresponding larger value for RCOMP. RFB2 should be large enough to keep the total divider power dissipation
small. 4.99 kΩ was chosen for RFB2 in this example, which results in a RFB1 value of 357 Ω for 12-V output.
8.3.22 Loop Compensation Components CCOMP, RCOMP and CHF
RCOMP, CCOMP and CHF configure the error amplifier gain and phase characteristics to produce a stable voltage
loop. For a quick start, follow the 4 steps listed below.
STEP1: Select fCROSS
By selecting one tenth of the switching frequency, fCROSS is calculated as follows:
fSW
10
fCROSS
=
= 23 kHz
(45)
STEP2: Determine required RCOMP
Knowing fCROSS, RCOMP is calculated as follows:
RCOMP = 2p x RS x AS x COUT x RFB2 x fCROSS
[W]
(46)
(47)
RCOMP = 2p x 7.41 mW x 10 x 514 µF x 4.99 kW x 23 kHz = 27.5 kW
The standard value of 27.4kΩ was selected for RCOMP
STEP3: Determine CCOMP to cancel load pole
Knowing RCOMP, CCOMP is calculated as follows:
æ
ç
è
ö
12V
9A
´ 514mF
÷
R
´ C
OUT
ø
LOAD
C
=
=
= 25nF
COMP
R
27.4kW
COMP
(48)
The standard value of 22nF was selected for CCOMP
STEP4: Determine CHF to cancel ESR zero
Knowing RCOMP and CCOMP, CHF is calculated as follows:
RESR x COUT x CCOMP
RCOMP x CCOMP - RESR x COUT
CHF
[F]
=
(49)
(50)
10mW x514µFx22nF
27.4kW x22nF-10mW x514µF
CHF
= 189pF
=
Half of the maximum ESR is assumed as a typical ESR. The standard value of 180pF was selected for CHF
.
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Table 1. LM5117 Frequency Analysis Formulas
SIMPLE FORMULA
COMPREHENSIVE FORMULA(1)
MODULATOR
TRANSFER
FUNCTION
s
s
1 +
1 +
^
^
wZ_ESR
wZ_ESR
VOUT
VOUT
A
M
x (1 +
) (1 +
+
)
=
x (1 +
)
A
M
=
s2
^
^
s
s
x
s
s
VCOMP
x
) (1 +
VCOMP
2
wP_LF
w
wP_HF
w
P_ESR
P_LF
wn
Modulator DC
Gain
RLOAD
1
RLOAD
x
AM
=
AM
=
RLOAD
wP_HF
RS x AS
RS x AS
1 +
x LO
ESR Zero
ESR Pole
1
1
wZ_ESR
=
wZ_ESR
=
RESR x COUT
R
ESR1 x COUT1
Not considered
1
wP_ESR
=
RESR1 x (COUT1 // COUT2
)
Dominant Load
Pole
1
1
1
+
wP_LF
=
wP_LF
=
(RLOAD + RESR1) x (COUT1 + COUT2
)
LO x (COUT1 + COUT2) x wP_HF
RLOAD x COUT
Sampled Gain
Inductor Pole
Not considered
fSW
K ꢀ 0.5
wP_HF =
or wP_HF Q x w
=
n
Quality Factor
Not considered
Not considered
1
Q =
p(K - 0.5)
Sub-harmonic
Double Pole
wSW
fSW
wn =
= p x fSW or fn =
2
2
K Factor
LO
K = 1
K =
RRAMP x CRAMP x RS x AS
FEEDBACK
TRANSFER
FUNCTION
s
Z_EA
s
1 +
1 +
^
^
w
VCOMP
w
VCOMP
Z_EA
-
= AFB
x
-
= AFB
x
s
^
s
^
VOUT
s x (1+
)
VOUT
s x (1+
)
w
P_EA
w
P_EA
Feedback DC
Gain
1
1
AFB
=
AFB
=
RFB2 x (CCOMP + CHF
)
RFB2 x (CCOMP + CHF)
Mid-band Gain
RCOMP
RFB2
RCOMP
RFB2
AFB_MID
=
AFB_MID
=
Low
Frequency
Zero
1
1
=
=
wZ_EA
wZ_EA
RCOMP x CCOMP
RCOMP x CCOMP
High
Frequency
Pole
1
1
wP_EA
=
wP_EA
=
RCOMP x CHF
R
COMP x (CHF // CCOMP
)
(1) Comprehensive Equation includes an inductor pole and a gain peaking at fSW/2, which caused by sampling effect of the current mode
control. Also it assumes that a ceramic capacitor COUT2 (No ESR) is connected in parallel with COUT1. RESR1 represents ESR of COUT1
.
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Table 1. LM5117 Frequency Analysis Formulas (continued)
SIMPLE FORMULA
COMPREHENSIVE FORMULA(1)
OPEN-LOOP
RESPONSE
s
s
s
Z_EA
s
Z_EA
1 +
1 +
1 +
1 +
w
w
wZ_ESR
w
Z_ESR
x(1 +
)
(1 +
)
T(s) = AM x AFB
x
x
T(s) = AM x AFB
x(1 +
) (1 +
+
)
s
s
s
s
s
s
s x
s2
x
) (1 +
x
s x
(1 +
)
w
w
P_EA
P_LF
2
w
wP_LF
w
wP_HF
P_EA
P_ESR
wn
s
AM x AFB
s
1 +
T(s) =
wZ_ESR
AM x AFB
s
x(1 +
) (1 +
+
)
T(s) =
s2
s
s
x
s
x
) (1 +
when
wZ_EA = wP_LF
wP_EA = wZ_ESR
&
2
wP_EA
w
wP_HF
P_ESR
wn
when wZ_EA = wP_LF
Cross Over
Frequency
(Open Loop
Bandwidth)
RCOMP
2 x ' x RS x RFB2 x AS x COUT
RCOMP
2 x ' x RS x RFB2 x AS x (COUT1 + COUT2
fCROSS
=
fCROSS
=
)
when
wZ_EA = wP_LF
wP_EA = wZ_ESR
&
wP_EA = wZ_ESR
when wZ_EA = wP_LF
&
wP_HF
wP_ESR
fCROSS <
fCROSS
<
&
&
2 x p x 10
2 x p x 10
Maximum
Cross Over
Frequency
fSW
5
fSW
4 x Q
2 -1
fCROSS_MAX
=
x
(
1 + 4 x Q
)
fCROSS_MAX
=
The frequency at which 45° phase shift occurs in modulator phase
characteristics.
8.4 Application Curves
Figure 34. Typical Efficiency vs Load Current
Figure 33. Start-Up with Resistive Load
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Application Curves (continued)
8.4.1 Constant Current Regulator
The LM5117 can be configured as a constant current regulator by using the current monitor feature (CM) as the
feedback input. A voltage divider at the VCCDIS pin from VOUT to AGND can be used to protect against output
over-voltage. When the VCCDIS pin voltage is greater than the VCCDIS threshold, the controller disables the
VCC regulator and the VCC pin voltage decays. When the VCC pin voltage is less than the VCC UV threshold,
both HO and LO outputs stop switching. Due to the time delay required for VCC to decay below the VCC UV
threshold, the over-voltage protection operates in hiccup mode. See Figure 35.
V
IN
100kW
15 kW
C
IN
UVLO VIN RES DEMB VCC
SW
C
VCC
D
HB
Hiccup Mode OVP
Triggered at 13.4V
LM5117
100 kW
HB
RAMP
V
OUT
C
HB
1500 pF
Q
H
V
68 µH
OUT
HO
SW
3.24 kW
CC Mode: 2A
80 µF
VCCDIS
Q
L
LO
332W
CS
47 mW
CSG
CM
0.022 µF
3.24 kW
2.37 kW
COMP
FB
RT
SS
AGND PGND
22.1 kW
0.47 µF
Current Control (CC)
Figure 35. Constant Current Regulator With Hiccup Mode Output OVP
8.4.2 Constant Voltage and Constant Current Regulator
The LM5117 also can be configured as a constant voltage and constant current regulator, known as CV+CC
regulator. In this configuration, there is much less variation in the current limiting as compared to peak cycle-by-
cycle current limiting of the inductor current. The LMV431 and the PNP transistor create a voltage-to-current
amplifier in the current loop. This amplifier circuitry does not affect the normal operation when the output current
is less than the current limit set-point. When the output current is greater than the set-point, the PNP transistor
sources a current into CRAMP and increases the positive slope of emulated inductor current ramp until the output
current is less than or equal to the current limit set-point. See Figure 36 and Figure 37.
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LM5117, LM5117-Q1
SNVS698F –APRIL 2011–REVISED AUGUST 2015
www.ti.com
Application Curves (continued)
V
IN
Current Control (CC)
100 kW
C
IN
V
CC
UVLO VIN RES DEMB VCC
C
VCC
SW
10 kW
100W
15 kW
D
HB
100 kW
LM5117
PNP
HB
RAMP
C
HB
1 nF
Q
V
OUT
H
68 mH
1500 pF
HO
100 kW
200 kW
CV Mode : 5V
CC Mode: 2A
CM
SW
LMV431
Q
L
80 mF
LO
VCCDIS
CS
47 mW
V
OUT
CSG
0.1 mF
34.8 kW
3.24 kW
COMP
FB
RT
SS
AGND PGND
619W
22.1 kW
0.33 mF x2
Voltage Control (CV)
Figure 36. Constant Voltage Regulator with Accurate Current Limit
Figure 37. Current Limit Comparison
34
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Product Folder Links: LM5117 LM5117-Q1
LM5117, LM5117-Q1
www.ti.com
SNVS698F –APRIL 2011–REVISED AUGUST 2015
9 Power Supply Recommendations
The LM5117 is a power management device. The power supply for the device is any DC voltage source within
the specified input range.
10 Layout
10.1 Layout Guideline
Controller
QL
Place controller as
close to the switches
Inductor
QH
RSENSE
COUT
COUT
CIN
CIN
VIN GND GND
Figure 38. Layout Example
10.1.1 PC Board Layout Recommendation
VOUT
In a buck regulator the primary switching loop consists of the input capacitor, NMOS power switches and current
sense resistor. Minimizing the area of this loop reduces the stray inductance and minimizes noise and possible
erratic operation. High quality input capacitors should be placed as close as possible to the NMOS power
switches, with the VIN side of the capacitor connected directly to the high-side NMOS drain and the ground side
of the capacitor connected as close as possible to the current sense resistor ground connection.
Connect all of the low power ground connections (RUV1, RT, RFB1, CSS, CRES, CCM, CVIN, CRAMP) directly to the
regulator AGND pin. Connect CVCC directly to the regulator PGND pin. Note that CVIN and CVCC must be as
physically close as possible to the IC. AGND and PGND must be directly connected together through a top-side
copper pattern connected to the exposed pad. Ensure no high current flows beneath the underside exposed pad.
The LM5117 has an exposed thermal pad to aid power dissipation. Adding several vias under the exposed pad
helps conduct heat away from the IC. The junction to ambient thermal resistance varies with application. The
most significant variables are the area of copper in the PC board, the number of vias under the exposed pad and
the amount of forced air cooling. The integrity of the solder connection from the IC exposed pad to the PC board
is critical. Excessive voids greatly decrease the thermal dissipation capacity.
The highest power dissipating components are the two power switches. Selecting NMOS switches with exposed
pads aids the power dissipation of these devices.
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Product Folder Links: LM5117 LM5117-Q1
LM5117, LM5117-Q1
SNVS698F –APRIL 2011–REVISED AUGUST 2015
www.ti.com
11 Device and Documentation Support
11.1 Related Links
The table below lists quick access links. Categories include technical documents, support and community
resources, tools and software, and quick access to sample or buy.
Table 2. Related Links
TECHNICAL
DOCUMENTS
TOOLS &
SOFTWARE
SUPPORT &
COMMUNITY
PARTS
PRODUCT FOLDER
SAMPLE & BUY
LM5117
Click here
Click here
Click here
Click here
Click here
Click here
Click here
Click here
Click here
Click here
LM5117-Q1
11.2 Community Resources
The following links connect to TI community resources. Linked contents are provided "AS IS" by the respective
contributors. They do not constitute TI specifications and do not necessarily reflect TI's views; see TI's Terms of
Use.
TI E2E™ Online Community TI's Engineer-to-Engineer (E2E) Community. Created to foster collaboration
among engineers. At e2e.ti.com, you can ask questions, share knowledge, explore ideas and help
solve problems with fellow engineers.
Design Support TI's Design Support Quickly find helpful E2E forums along with design support tools and
contact information for technical support.
11.3 Trademarks
E2E is a trademark of Texas Instruments.
WEBENCH is a registered trademark of Texas Instruments.
All other trademarks are the property of their respective owners.
11.4 Electrostatic Discharge Caution
These devices have limited built-in ESD protection. The leads should be shorted together or the device placed in conductive foam
during storage or handling to prevent electrostatic damage to the MOS gates.
11.5 Glossary
SLYZ022 — TI Glossary.
This glossary lists and explains terms, acronyms, and definitions.
12 Mechanical, Packaging, and Orderable Information
The following pages include mechanical, packaging, and orderable information. This information is the most
current data available for the designated devices. This data is subject to change without notice and revision of
this document. For browser-based versions of this data sheet, refer to the left-hand navigation.
36
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Copyright © 2011–2015, Texas Instruments Incorporated
Product Folder Links: LM5117 LM5117-Q1
PACKAGE OPTION ADDENDUM
www.ti.com
5-Jun-2015
PACKAGING INFORMATION
Orderable Device
LM5117PMH/NOPB
LM5117PMHE/NOPB
LM5117PMHX/NOPB
LM5117PSQ/NOPB
LM5117PSQE/NOPB
LM5117PSQX/NOPB
LM5117QPMH/NOPB
LM5117QPMHE/NOPB
LM5117QPMHX/NOPB
LM5117QPSQ/NOPB
LM5117QPSQE/NOPB
LM5117QPSQX/NOPB
Status Package Type Package Pins Package
Eco Plan
Lead/Ball Finish
MSL Peak Temp
Op Temp (°C)
-40 to 125
-40 to 125
-40 to 125
-40 to 125
-40 to 125
-40 to 125
-40 to 125
-40 to 125
-40 to 125
-40 to 125
-40 to 125
-40 to 125
Device Marking
Samples
Drawing
Qty
(1)
(2)
(6)
(3)
(4/5)
ACTIVE
HTSSOP
HTSSOP
HTSSOP
WQFN
PWP
20
20
20
24
24
24
20
20
20
24
24
24
73
Green (RoHS
& no Sb/Br)
CU SN
CU SN
CU SN
CU SN
CU SN
CU SN
CU SN
CU SN
CU SN
CU SN
CU SN
CU SN
Level-3-260C-168 HR
Level-3-260C-168 HR
Level-3-260C-168 HR
Level-1-260C-UNLIM
Level-1-260C-UNLIM
Level-1-260C-UNLIM
Level-3-260C-168 HR
Level-3-260C-168 HR
Level-3-260C-168 HR
Level-1-260C-UNLIM
Level-1-260C-UNLIM
Level-1-260C-UNLIM
LM5117
PMH
ACTIVE
ACTIVE
ACTIVE
ACTIVE
ACTIVE
ACTIVE
ACTIVE
ACTIVE
ACTIVE
ACTIVE
ACTIVE
PWP
PWP
RTW
RTW
RTW
PWP
PWP
PWP
RTW
RTW
RTW
250
2500
1000
250
Green (RoHS
& no Sb/Br)
LM5117
PMH
Green (RoHS
& no Sb/Br)
LM5117
PMH
Green (RoHS
& no Sb/Br)
L5117P
L5117P
L5117P
WQFN
Green (RoHS
& no Sb/Br)
WQFN
4500
73
Green (RoHS
& no Sb/Br)
HTSSOP
HTSSOP
HTSSOP
WQFN
Green (RoHS
& no Sb/Br)
LM5117
QMH
250
Green (RoHS
& no Sb/Br)
LM5117
QMH
2500
1000
250
Green (RoHS
& no Sb/Br)
LM5117
QMH
Green (RoHS
& no Sb/Br)
L5117Q
L5117Q
L5117Q
WQFN
Green (RoHS
& no Sb/Br)
WQFN
4500
Green (RoHS
& no Sb/Br)
(1) The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2) Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check http://www.ti.com/productcontent for the latest availability
information and additional product content details.
TBD: The Pb-Free/Green conversion plan has not been defined.
Addendum-Page 1
PACKAGE OPTION ADDENDUM
www.ti.com
5-Jun-2015
Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements for all 6 substances, including the requirement that
lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes.
Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and package, or 2) lead-based die adhesive used between
the die and leadframe. The component is otherwise considered Pb-Free (RoHS compatible) as defined above.
Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame retardants (Br or Sb do not exceed 0.1% by weight
in homogeneous material)
(3) MSL, Peak Temp. - The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature.
(4) There may be additional marking, which relates to the logo, the lot trace code information, or the environmental category on the device.
(5) Multiple Device Markings will be inside parentheses. Only one Device Marking contained in parentheses and separated by a "~" will appear on a device. If a line is indented then it is a continuation
of the previous line and the two combined represent the entire Device Marking for that device.
(6) Lead/Ball Finish - Orderable Devices may have multiple material finish options. Finish options are separated by a vertical ruled line. Lead/Ball Finish values may wrap to two lines if the finish
value exceeds the maximum column width.
Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI bases its knowledge and belief on information
provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and
continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals.
TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release.
In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI to Customer on an annual basis.
OTHER QUALIFIED VERSIONS OF LM5117, LM5117-Q1 :
Catalog: LM5117
•
Automotive: LM5117-Q1
•
NOTE: Qualified Version Definitions:
Catalog - TI's standard catalog product
•
Automotive - Q100 devices qualified for high-reliability automotive applications targeting zero defects
•
Addendum-Page 2
PACKAGE MATERIALS INFORMATION
www.ti.com
5-Jun-2015
TAPE AND REEL INFORMATION
*All dimensions are nominal
Device
Package Package Pins
Type Drawing
SPQ
Reel
Reel
A0
B0
K0
P1
W
Pin1
Diameter Width (mm) (mm) (mm) (mm) (mm) Quadrant
(mm) W1 (mm)
LM5117PMHE/NOPB HTSSOP PWP
LM5117PMHX/NOPB HTSSOP PWP
20
20
24
24
24
20
20
24
24
24
250
2500
1000
250
178.0
330.0
178.0
178.0
330.0
178.0
330.0
178.0
178.0
330.0
16.4
16.4
12.4
12.4
12.4
16.4
16.4
12.4
12.4
12.4
6.95
6.95
4.3
7.1
7.1
4.3
4.3
4.3
7.1
7.1
4.3
4.3
4.3
1.6
1.6
1.3
1.3
1.3
1.6
1.6
1.3
1.3
1.3
8.0
8.0
8.0
8.0
8.0
8.0
8.0
8.0
8.0
8.0
16.0
16.0
12.0
12.0
12.0
16.0
16.0
12.0
12.0
12.0
Q1
Q1
Q1
Q1
Q1
Q1
Q1
Q1
Q1
Q1
LM5117PSQ/NOPB
LM5117PSQE/NOPB
LM5117PSQX/NOPB
WQFN
WQFN
WQFN
RTW
RTW
RTW
4.3
4500
250
4.3
LM5117QPMHE/NOPB HTSSOP PWP
LM5117QPMHX/NOPB HTSSOP PWP
6.95
6.95
4.3
2500
1000
250
LM5117QPSQ/NOPB
LM5117QPSQE/NOPB
LM5117QPSQX/NOPB
WQFN
WQFN
WQFN
RTW
RTW
RTW
4.3
4500
4.3
Pack Materials-Page 1
PACKAGE MATERIALS INFORMATION
www.ti.com
5-Jun-2015
*All dimensions are nominal
Device
Package Type Package Drawing Pins
SPQ
Length (mm) Width (mm) Height (mm)
LM5117PMHE/NOPB
LM5117PMHX/NOPB
LM5117PSQ/NOPB
HTSSOP
HTSSOP
WQFN
PWP
PWP
RTW
RTW
RTW
PWP
PWP
RTW
RTW
RTW
20
20
24
24
24
20
20
24
24
24
250
2500
1000
250
213.0
367.0
210.0
210.0
367.0
213.0
367.0
210.0
210.0
367.0
191.0
367.0
185.0
185.0
367.0
191.0
367.0
185.0
185.0
367.0
55.0
38.0
35.0
35.0
35.0
55.0
38.0
35.0
35.0
35.0
LM5117PSQE/NOPB
LM5117PSQX/NOPB
LM5117QPMHE/NOPB
LM5117QPMHX/NOPB
LM5117QPSQ/NOPB
LM5117QPSQE/NOPB
LM5117QPSQX/NOPB
WQFN
WQFN
4500
250
HTSSOP
HTSSOP
WQFN
2500
1000
250
WQFN
WQFN
4500
Pack Materials-Page 2
MECHANICAL DATA
PWP0020A
MXA20A (Rev C)
www.ti.com
MECHANICAL DATA
RTW0024A
SQA24A (Rev B)
www.ti.com
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