STMICROELECTRONICS L6727

L6727
Single phase PWM controller
Feature
■
Flexible power supply from 5 V to 12 V
■
Power conversion input as low as 1.5 V
■
1 % output voltage accuracy
■
High-current integrated drivers
■
Adjustable output voltage
■
0.8 V internal reference
■
Simple voltage mode control loop
Description
■
Sensorless and programmable OCP across
Low-side RdsON
■
Oscillator internally fixed at 300 kHz
■
Internal Soft-start
■
LS-LESS to manage pre-bias start-up
L6727 is a single-phase step-down controller with
integrated high-current drivers that provides
complete control logic, protections and reference
voltage to realize in an easy and simple way
general DC-DC converters by using a compact
SO-8 package.
■
Disable function
■
OV / UV protection
■
FB disconnection protection
■
SO-8 package
SO-8
Device flexibility allows managing conversions
with power input VIN as low as 1.5 V and device
supply voltage in the range of 5 V to 12 V.
Applications
■
Subsystem power supply (MCH, IOCH, PCI...)
■
Memory and termination supply
■
CPU and DSP power supply
■
Distributed power supply
■
General DC / DC converters
L6727 provides simple control loop with voltagemode error-amplifier. The integrated 0.8 V
reference allows regulating output voltages with
±1 % accuracy over line and temperature
variations. Oscillator is internally fixed to 300 kHz.
L6727 provides programmable over current
protection as well as over and under voltage
protection. Current information is monitored
across the low-side MOSFET RdsON saving the
use of expensive and space-consuming sense
resistors while output voltage is monitored
through FB pin.
FB disconnection protection prevents excessive
and dangerous output voltages in case of floating
FB pin.
Table 1.
Device summary
Order codes
Package
L6727
Packaging
Tube
SO-8
L6727TR
March 2010
Tape and reel
Doc ID 12933 Rev 4
1/34
www.st.com
34
Contents
L6727
Contents
1
2
3
Typical application circuit and block diagram . . . . . . . . . . . . . . . . . . . . 4
1.1
Application circuit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
1.2
Block diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
Pins description and connection diagrams . . . . . . . . . . . . . . . . . . . . . . 5
2.1
Pin descriptions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5
2.2
Thermal data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6
Electrical specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6
3.1
Absolute maximum ratings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6
3.2
Electrical characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7
4
Device description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
5
Driver section . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10
5.1
6
7
Soft-start and disable . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11
6.1
Low-side-less start up (LSLess) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11
6.2
Enable / disable . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12
Overcurrent protection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13
7.1
8
9
2/34
Power dissipation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10
Overcurrent threshold setting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13
Output voltage monitor and protections . . . . . . . . . . . . . . . . . . . . . . . . 14
8.1
Undervoltage protection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14
8.2
Overvoltage protection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14
8.3
Feedback disconnection protection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14
8.4
Undervoltage lock out . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14
Application details . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
9.1
Output voltage selection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
9.2
Compensation network . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
Doc ID 12933 Rev 4
L6727
10
11
Contents
9.3
Layout guidelines . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17
9.4
Embedding L6727-based VRs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19
Application information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20
10.1
Output inductor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20
10.2
Output capacitors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21
10.3
Input capacitors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21
20 A demonstration board . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22
11.1
12
Board description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26
11.1.1
Power input (VIN) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26
11.1.2
Power output (VOUT) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26
11.1.3
IC additional supply (VCC) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26
11.1.4
Test points . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26
11.1.5
Demonstration board efficiency . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26
5 A demonstration board . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27
12.1
Board description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30
12.1.1
Power input (VIN) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30
12.1.2
Power iutput (VOUT) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30
12.1.3
IC additional supply (VCC) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30
12.1.4
Test points . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30
12.1.5
Demonstration board efficiency . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31
13
Package mechanical data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32
14
Revision history . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34
Doc ID 12933 Rev 4
3/34
Typical application circuit and block diagram
L6727
1
Typical application circuit and block diagram
1.1
Application circuit
Figure 1.
Typical application circuit
VIN = 1.5V to 19V (**)
VCC = 5V to 12V
CDEC
ROCSET
D
5
(*)
VCC
COMP /
DIS / OC
L6727
7
BOOT
CF
CP
RF
6
UGATE
PHASE
FB
LGATE
ROS
RD
1
CBOOT
HS
RgHS
8
L
RgLS
4
LS
GND
RFB
CBULK
CHF
2
RSN
Vout
COUT
LOAD
CSN
3
L6727 Reference Schematic
(*) ROCSET not to be connected when VCC > 5V
(**) Up to 12V with Vcc > 5V
1.2
Block diagram
Block diagram
VCC
Figure 2.
BOOT
DISABLE
PWM
300 kHz
OSCILLATOR
+
-
COMP
/ DIS / OC
L6727
4/34
FB
ERROR
AMPLIFIER
Doc ID 12933 Rev 4
0.8V
ADAPTIVE ANTI
CROSS CONDUCTION
IOCSET
CURRENT READ
& OCP
Vout Monitor
CONTROL LOGIC
& PROTECTIONS
HS
UGATE
PHASE
VCC
LS
LGATE
GND
L6727
2
Pins description and connection diagrams
Pins description and connection diagrams
Figure 3.
Pins connection (top view)
BOOT
UGATE
GND
LGATE
2.1
1
8
2
7
3
4
L6727
6
5
PHASE
COMP / DIS / OC
FB
VCC
Pin descriptions
Table 2.
Pins descriptions
Pin #
Name
1
BOOT
HS driver supply.
Connect through a capacitor (100 nF) to the floating node (LS-drain) pin
and provide necessary bootstrap diode from VCC.
2
UGATE
HS driver output. Connect to HS MOSFET gate.
3
GND
4
LGATE
5
VCC
6
FB
Function
All internal references, logic and drivers are connected to this pin.
Connect to the PCB ground plane.
LS driver output. Connect to LS MOSFET gate.
Device and LS driver power supply.
Operative range from 4.1 V to 13.2 V. Filter with at least 1μF MLCC to GND.
Error Amplifier Inverting Input.
Connect with a resistor RFB to the output regulated voltage. Additional
resistor ROS to GND may be used to regulate voltages higher than the
reference.
7
COMP. Error amplifier output. Connect with an RF - CF // CP to FB to
compensate the control-loop.
DIS. The device can be disabled by forcing this pin lower than 0.5V(typ). To
disable the device, the external pull-down need to overcome 10mA of
COMP / DIS
COMP output current for about 15 μs. Once disabled, COMP output current
/ OC
drops to 20 μA.
OC. Over current threshold set. Connect with an ROCSET resistor to VCC
(ONLY IF VCC is supplied by 5 V bus) to program OC threshold. When
VCC > 5V, ROCSET need to be not-connected.
8
HS driver return path, current-reading and adaptive-dead-time monitor.
Connect to the LS drain to sense RdsON drop to measure the output current.
This pin is also used by the adaptive-dead-time control circuitry to monitor
when HS MOSFET is OFF.
PHASE
Doc ID 12933 Rev 4
5/34
Electrical specifications
2.2
L6727
Thermal data
Table 3.
Thermal data
Symbol
Parameter
Value
Unit
RthJA
Thermal resistance junction to ambient (1)
85
°C/W
TMAX
Maximum junction temperature
150
°C
TSTG
Storage temperature range
-40 to 150
°C
TJ
Junction temperature range
-20 to 150
°C
1. Measured with the component mounted on a 2S2P board in free air (6.7cm x 6.7cm, 35μm (P) and
17.5 μm (S) copper thickness).
3
Electrical specifications
3.1
Absolute maximum ratings
Table 4.
Absolute maximum ratings
Symbol
VCC
Parameter
to GND
VBOOT
to PHASE
to GND
VUGATE
to PHASE
to PHASE; t < 50 ns
to GND
VPHASE
to GND
VLGATE
to GND
to GND; t < 50 ns
COMP to GND
FB to GND
6/34
Doc ID 12933 Rev 4
Value
Unit
-0.3 to 15
V
15
45
V
-0.3 to (VBOOT - VPHASE) + 0.3
-1
VBOOT + 0.3
V
-8 to 30
V
-0.3 to VCC + 0.3
-1
V
-0.3 to 7
V
-0.3 to 3.6
V
L6727
Electrical specifications
3.2
Electrical characteristics
VCC = 12 V; TA = -20 °C to +85 °C, unless otherwise specified.
Table 5.
Electrical characteristics
Symbol
Parameter
Test conditions
Min.
Typ.
Max.
Unit
13.2
V
13.2
V
19.0
V
Recommended operating conditions
VCC
Device supply voltage
VIN
Conversion input voltage
4.1
See Figure 1
VCC < 7.0 V
Supply current and power-ON
ICC
IBOOT
VCC supply current
UGATE and LGATE = OPEN
BOOT supply current
UGATE = OPEN; PHASE to GND
VCC turn-ON
VCC rising
6
mA
0.5
mA
4.1
V
UVLO
Hysteresis
0.2
V
Oscillator
0 °C to +70 °C
FSW
270
300
330
kHz
250
300
350
kHz
Main oscillator accuracy
ΔVOSC
PWM ramp amplitude
dMAX
Maximum duty cycle
1.5
V
80
%
Reference
Output voltage accuracy
VOUT = 0.8 V, TA = 0 °C to 70 °C
VOUT = 0.8 V
-1
-
-1.5
1
%
1.5
%
Error amplifier
A0
GBWP
DC gain(1)
Gain-bandwidth
product(1)
(1)
SR
Slew-rate
IFB
Input bias current
Sourced from FB
DIS
Disable threshold
COMP falling
0.43
120
dB
15
MHz
8
V/μs
100
nA
0.5
V
Gate drivers
IUGATE
HS source current
BOOT - PHASE = 5 V to 12 V
1.5
A
RUGATE
HS sink resistance
BOOT - PHASE = 5 V to 12 V
1.1
Ω
ILGATE
LS source current
VCC = 5 V to 12 V
1.5
A
RLGATE
LS sink resistance
VCC = 5 V to 12 V
0.65
Ω
Overcurrent protection
IOCSET
OCSET current source
Sunk from COMP pin, before SS
Doc ID 12933 Rev 4
55
60
65
μA
7/34
Electrical specifications
Table 5.
Symbol
L6727
Electrical characteristics (continued)
Parameter
Test conditions
VCC_OC
OC Switch-over threshold
VCC rising
VOCTH
Fixed OC threshold
VPHASE to GND, VCC > VCC_OC
Min.
Typ.
Max.
Unit
8
V
-400
mV
Over and undervoltage protections
OVP
OVP threshold
FB rising
1
V
UVP
UVP threshold
FB falling
0.6
V
1. Guaranteed by design, not subject to test.
8/34
Doc ID 12933 Rev 4
L6727
4
Device description
Device description
L6727 is a single-phase PWM controller with embedded high-current drivers that provides
complete control logic and protections to realize in an easy and simple way a general DCDC step-down converter. Designed to drive N-channel MOSFETs in a synchronous buck
topology, with its high level of integration this 8-pin device allows reducing cost and size of
the power supply solution.
L6727 is designed to operate from a 5 V or 12 V supply bus. Thanks to the high precision
0.8V internal reference, the output voltage can be precisely regulated to as low as 0.8 V with
±1 % accuracy over line and temperature variations (between 0 °C and +70 °C).
The switching frequency is internally set to 300 kHz.
This device provides a simple control loop with a voltage-mode error-amplifier. The erroramplifier features a 15 MHz gain-bandwidth product and 8V/µs slew rate, allowing high
regulator bandwidth for fast transient response.
To avoid load damages, L6727 provides over current protection as well as over voltage,
under voltage and feedback disconnection protection. When the device is supplied from 5 V,
over current trip threshold is programmable by a simple resistor. Output current is monitored
across Low-side MOSFET RdsON, saving the use of expensive and space-consuming sense
resistor. Output voltage and feedback disconnection are monitored through FB pin.
L6727 implements soft-start increasing the internal reference from 0 V to 0.8 V in 5.1 ms
(typ) in closed loop regulation. Low-side-less feature allows the device to perform soft-start
over pre-biased output avoiding high current return through the output inductor and
dangerous negative spike at the load side.
Doc ID 12933 Rev 4
9/34
Driver section
5
L6727
Driver section
The integrated high-current drivers allow using different types of power MOSFET (also
multiple MOSFETs to reduce the equivalent RdsON), maintaining fast switching transition.
The driver for the high-side MOSFET uses BOOT pin for supply and PHASE pin for return.
The driver for low-side MOSFET uses the VCC pin for supply and GND pin for return.
The controller embodies an anti-shoot-through and adaptive dead-time control to minimize
low side body diode conduction time, maintaining good efficiency while saving the use of
Schottky diode:
●
to check high-side MOSFET turn off, PHASE pin is sensed. When the voltage at
PHASE pin drops down, the low-side MOSFET gate drive is suddenly applied;
●
to check low-side MOSFET turn off, LGATE pin is sensed. When the voltage at LGATE
has fallen, the high-side MOSFET gate drive is suddenly applied.
If the current flowing in the inductor is negative, voltage on PHASE pin will never drop. To
allow the low-side MOSFET to turn-on even in this case, a watchdog controller is enabled: if
the source of the high-side MOSFET doesn't drop, the low side MOSFET is switched on so
allowing the negative current of the inductor to recirculate. This mechanism allows the
system to regulate even if the current is negative.
Power conversion input is flexible: 5 V, 12 V bus or any bus that allows the conversion (See
maximum duty cycle limitation and recommended operating conditions, in Table 5) can be
chosen freely.
5.1
Power dissipation
L6727 embeds high current MOSFET drivers for both high side and low side MOSFETs: it is
then important to consider the power that the device is going to dissipate in driving them in
order to avoid overcoming the maximum junction operative temperature.
Two main terms contribute in the device power dissipation: bias power and drivers' power.
●
Device bias power (PDC) depends on the static consumption of the device through the
supply pins and it is simply quantifiable as follow (assuming to supply HS and LS
drivers with the same VCC of the device):
P DC = V CC ⋅ ( I CC + I BOOT )
●
Drivers power is the power needed by the driver to continuously switch on and off the
external MOSFETs; it is a function of the switching frequency and total gate charge of
the selected MOSFETs. It can be quantified considering that the total power PSW
dissipated to switch the MOSFETs (easy calculable) is dissipated by three main
factors: external gate resistance (when present), intrinsic MOSFET resistance and
intrinsic driver resistance. This last term is the important one to be determined to
calculate the device power dissipation. The total power dissipated to switch the
MOSFETs results:
P SW = F SW ⋅ [ Q gHS ⋅ ( V BOOT – V PHASE ) + Q gLS ⋅ V CC ]
where VBOOT - VPHASE is the voltage across the bootstrap capacitor. External gate
resistors helps the device to dissipate the switching power since the same power PSW
will be shared between the internal driver impedance and the external resistor resulting
in a general cooling of the device.
10/34
Doc ID 12933 Rev 4
L6727
6
Soft-start and disable
Soft-start and disable
L6727 implements a soft-start to smoothly charge the output filter avoiding high in-rush
currents to be required from the input power supply. The device progressively increases the
internal reference from 0 V to 0.8 V in about 5.1 ms, in closed loop regulation, gradually
charging the output capacitors to the final regulation voltage.
In the event of an overcurrent triggering during soft start, the over current logic will override
the soft start sequence and will shut down both the high side and low side gates for the
internal soft start residual time (up to 2048 clock cycles) plus 2048 clock cycles, then it will
begin a new soft start.
The device begins soft start phase only when VCC power supply is above UVLO threshold
and overcurrent threshold setting phase has been completed.
6.1
Low-side-less start up (LSLess)
In order to manage start up over pre-biased output, L6727 performs a special sequence in
enabling LS driver to switch: during the soft-start phase, LS driver results disabled
(LS = OFF) until HS starts to switch. This avoids the dangerous negative spike on the output
voltage that can happen if starting over a pre-biased output.
If the output voltage is pre-biased to a voltage lower than the programmed one, neither HS
nor LS will turn on until the soft start ramp exceeds the output pre-bias voltage; then VOUT
will ramp up from there, without any drop or current return.
If the output voltage is pre-biased to a voltage higher than the programmed one, HS would
never start to switch. In this case, at the end of soft start time, LS is enabled and discharges
the output to the final regulation value.
This particular feature of the device masks the LS turn-on only from the control loop point of
view: protections by-pass LSLESS, turning ON the LS MOSFET in case of need.
Figure 4.
LSless startup (left) vs non-lsless startup (right)
Doc ID 12933 Rev 4
11/34
Soft-start and disable
6.2
L6727
Enable / disable
The device can be disabled by externally pushing COMP / DIS pin under 0.5 V (typ). In
disable condition HS and LS MOSFETs are turned off, and a 20 μA current is sourced from
COMP / DIS pin. Setting free the pin, this current pulls it over the threshold and the device
enables again performing a new SS.
To disable the device, the external pull-down needs to overcome 10 mA of COMP output
current for about 15 μs. Once disabled, COMP output current drops to 20μA.
Figure 5.
12/34
Start up sequence; VCC = 5V (Left) overcurrent hiccup (Right)
Doc ID 12933 Rev 4
L6727
7
Overcurrent protection
Overcurrent protection
The overcurrent feature protects the converter from a shorted output or overload, by sensing
the output current information across the low side MOSFET drain-source on-resistance,
RdsON. This method reduces cost and enhances converter efficiency by avoiding the use of
expensive and space-consuming sense resistors.
The low side RdsON current sense is implemented by comparing the voltage at the PHASE
node when LS MOSFET is turned on with the programmed OCP threshold voltage,
internally held. If the monitored voltage drop (GND to PHASE) exceeds this threshold, an
overcurrent event is detected. If two overcurrent events are detected in two consecutive
switching cycles, the protection will be triggered and the device will turn off both LS and HS
MOSFETs for 2048 clock cycles (plus internal SS remaining time, if triggered during a SS
phase); then it will begin a new soft-start.
If the overcurrent condition is not removed, the continuous fault will cause L6727 to go into a
hiccup mode with a typical period of 13.6 ms (Figure 5), guaranteeing safe load protection
and very low power dissipation.
7.1
Overcurrent threshold setting
When supplied with VCC = 5 V, L6727 allows to easily program an overcurrent threshold
ranging from 50 mV to 500 mV, simply by adding a resistor (ROCSET) between COMP and
VCC.
During a short period of time (5.5 ms - 6.5 ms) following the first enable (given VCC over
UVLO threshold), an internal 60µA current (IOCSET) is sunk from COMP pin, determining a
voltage drop across ROCSET. This voltage drop, differentially sensed between VCC and
COMP, divided by a factor 3, will be sampled and internally held by the device as Over
Current Threshold until next VCC cycling. Differential sensing versus VCC allows OCSET
procedure to be fully independent from VIN rail. The OC setting procedure overall time
length ranges from 5.5 ms to 6.5 ms, proportionally to the threshold being set.
Connecting an ROCSET resistor between COMP and VCC, the programmed threshold will
be:
1 I OCSET ⋅ R OCSET
I OCth = --- ⋅ -------------------------------------------3
R dsON
ROCSET values range from 2.5 kΩ to 25 kΩ.
If the voltage drop across ROCSET is too low, the system will be very sensitive to start-up
inrush current and noise. This can result in a continuous OCP triggering and hiccup mode.
In this case, consider to increase ROCSET value.
In case ROCSET is not connected (and VCC = 5 V), the device will set the maximum
threshold.
If the device is supplied with a VCC higher than 7 V, ROCSET must be not connected. In this
case, as soon as VCC rises over VCC_OC (8 V typ.), L6727 switches OC threshold to 400mV
(internally fixed value).
See Figure 5 for OC threshold setting and soft start oscilloscope sample waveforms.
Doc ID 12933 Rev 4
13/34
Output voltage monitor and protections
8
L6727
Output voltage monitor and protections
L6727 monitors the voltage at FB pin and compares it to internal reference voltage in order
to provide Under Voltage and Over Voltage protections.
8.1
Undervoltage protection
If the voltage at FB pin drops below UV threshold (0.6 V typ), the device turns off both HS
and LS MOSFETs, waits for 2048 clock cycles and then performs a new soft start. If under
voltage condition is not removed, the device enters a hiccup mode with a typical period of
13.6 ms.
UVP is active from the end of soft start.
8.2
Overvoltage protection
If the voltage at FB pin rises over OV threshold (1 V typ), over voltage protection turns off HS
MOSFET and turns on LS MOSFET overriding PWM logic as long as over voltage is
detected.
OVP is always active with top priority as soon as over current threshold setting phase has
been completed.
8.3
Feedback disconnection protection
In order to provide load protection even if FB pin is not connected, a 100 nA bias current is
always sourced from this pin. If FB pin is not connected, this current will permanently pull up
FB over OVP threshold: thus LS will be latched on preventing output voltage from rising out
of control.
8.4
Undervoltage lock out
In order to avoid anomalous behaviors of the device when the supply voltage is too low to
support its internal rails, UVLO is provided: the device will start up when VCC reaches
UVLO upper threshold and will shutdown when VCC drops below UVLO lower threshold.
The 4.1 V maximum UVLO upper threshold allows L6727 to be supplied from 5 V and 12 V
busses in or-ing diode configuration.
14/34
Doc ID 12933 Rev 4
L6727
Application details
9
Application details
9.1
Output voltage selection
L6727 is capable to precisely regulate an output voltage as low as 0.8 V. In fact, the device
comes with a fixed 0.8 V internal reference that guarantees the output regulated voltage to
be within ±1 % tolerance over line and temperature variations between 0 °C and +70 °C
(excluding output resistor divider tolerance, when present).
Output voltage higher than 0.8 V can be easily achieved by adding a resistor ROS between
FB pin and ground. Referring to Figure 1, the steady state DC output voltage will be:
R FB ⎞
V OUT = V REF ⋅ ⎛⎝ 1 + ---------R OS⎠
where VREF is 0.8V.
9.2
Compensation network
The control loop showed in Figure 6 is a voltage mode control loop. The error amplifier is a
voltage mode type. The output voltage is regulated to the internal reference (when present,
offset resistor between FB node and GND can be neglected in control loop calculation).
Error Amplifier output is compared to oscillator saw-tooth waveform to provide PWM signal
to the driver section. PWM signal is then transferred to the switching node with VIN
amplitude. This waveform is filtered by the output filter.
The converter transfer function is the small signal transfer function between the output of the
EA and VOUT. This function has a double pole at frequency FLC depending on the L-COUT
resonance and a zero at FESR depending on the output capacitor ESR. The DC Gain of the
modulator is simply the input voltage VIN divided by the peak-to-peak oscillator voltage
ΔVOSC.
The compensation network closes the loop joining VOUT and EA output with transfer
function ideally equal to -ZF/ZFB.
Figure 6.
PWM control loop
VIN
OSC
ΔV OSC
_
L
+
R
V OUT
COUT
PWM
COMPARATOR
ERROR
AMPLIFIER
+
CF
ESR
VREF
_
RFB
RF
CS
RS
ZFB
CP
ZF
Doc ID 12933 Rev 4
15/34
Application details
L6727
Compensation goal is to close the control loop assuring high DC regulation accuracy, good
dynamic performances and stability. To achieve this, the overall loop needs high DC gain,
high bandwidth and good phase margin.
High DC gain is achieved giving an integrator shape to compensation network transfer
function. Loop bandwidth (F0dB) can be fixed choosing the right RF/RFB ratio, however, for
stability, it should not exceed FSW/2π. To achieve a good phase margin, the control loop gain
has to cross 0dB axis with -20 dB/decade slope.
As an example, Figure 7 shows an asymptotic bode plot of a type III compensation.
Figure 7.
Example of type III compensation.
Gain
[dB]
open loop
EA gain
FZ1 FZ2
FP2
FP1
closed
loop gain
compensation
gain
20log (RF/RFB)
open loop
converter gain
20log (VIN/ΔVOSC )
0dB
F0dB
FLC
●
●
16/34
FESR
Open loop converter singularities:
a)
1
F LC = ---------------------------------2π L ⋅ C OUT
b)
1
F ESR = -------------------------------------------2π ⋅ C OUT ⋅ ESR
Compensation Network singularities frequencies:
a)
1
F Z1 = -----------------------------2π ⋅ R F ⋅ C F
b)
1
F Z2 = ----------------------------------------------------2π ⋅ ( R FB + R S ) ⋅ C S
c)
1
F P1 = -------------------------------------------------CF ⋅ CP
2π ⋅ R F ⋅ ⎛⎝ ---------------------⎞⎠
CF + CP
d)
1
F P2 = -----------------------------2π ⋅ R S ⋅ C S
Doc ID 12933 Rev 4
Log (Freq)
L6727
Application details
To place the poles and zeroes of the compensation network, the following suggestions may
be followed:
a)
Set the gain RF/RFB in order to obtain the desired closed loop regulator bandwidth
according to the approximated formula (suggested values for RFB range from 2 kΩ
to 5 kΩ):
F 0dB ΔV OSC
RF
---------= ------------ ⋅ ------------------F LC
V IN
R FB
b)
Place FZ1 below FLC (typically 0.5*FLC):
1
C F = ----------------------------π ⋅ R F ⋅ F LC
c)
Place FP1 at FESR:
CF
C P = ---------------------------------------------------------2π ⋅ R F ⋅ C F ⋅ F ESR – 1
d)
Place FZ2 at FLC and FP2 at half of the switching frequency:
R FB
R S = -------------------------F SW
------------------ – 1
2 ⋅ F LC
1
C S = -----------------------------π ⋅ R S ⋅ F SW
9.3
e)
Check that compensation network gain is lower than open loop EA gain;
f)
Estimate phase margin obtained (it should be greater than 45 °) and repeat,
modifying parameters, if necessary.
Layout guidelines
L6727 provides control functions and high current integrated drivers to implement highcurrent step-down DC-DC converters. In this kind of application, a good layout is very
important.
The first priority when placing components for these applications has to be reserved to the
power section, minimizing the length of each connection and loop as much as possible. To
minimize noise and voltage spikes (EMI and losses) power connections (highlighted in
Figure 8) must be part of a power plane and anyway realized by wide and thick copper
traces: loop must be anyway minimized. The critical components, i.e. the power MOSFETs,
must be close one to the other. The use of multi-layer printed circuit board is recommended.
The input capacitance (CIN), or at least a portion of the total capacitance needed, has to be
placed close to the power section in order to eliminate the stray inductance generated by the
copper traces. Low ESR and ESL capacitors are preferred, MLCC are suggested to be
connected near the HS drain.
Use proper VIAs number when power traces have to move between different planes on the
PCB in order to reduce both parasitic resistance and inductance. Moreover, reproducing the
Doc ID 12933 Rev 4
17/34
Application details
L6727
same high-current trace on more than one PCB layer will reduce the parasitic resistance
associated to that connection.
Connect output bulk capacitors (COUT) as near as possible to the load, minimizing parasitic
inductance and resistance associated to the copper trace, also adding extra decoupling
capacitors along the way to the load when this results in being far from the bulk capacitors
bank.
Figure 8.
Power connections (heavy lines)
VIN
CIN
UGATE
PHASE
L
L6727
COUT
LGATE
LOAD
GND
Gate traces and phase trace must be sized according to the driver RMS current delivered to
the power MOSFET. The device robustness allows managing applications with the power
section far from the controller without losing performances. Anyway, when possible, it is
recommended to minimize the distance between controller and power section. See Figure 9
for drivers current paths.
Small signal components and connections to critical nodes of the application, as well as
bypass capacitors for the device supply, are also important. Locate bypass capacitor (VCC
and Bootstrap capacitor) and loop compensation components as close to the device as
practical. For over current programmability, place ROCSET close to the device and avoid
leakage current paths on COMP / OC pin, since the internal current source is only 60μA.
Systems that do not use Schottky diode in parallel to the Low-Side MOSFET might show big
negative spikes on the phase pin. This spike must be limited within the absolute maximum
ratings (for example, adding a gate resistor in series to HS MOSFET gate, or a phase
resistor in series to PHASE pin), as well as the positive spike, but has an additional
consequence: it causes the bootstrap capacitor to be over-charged. This extra-charge can
cause, in the worst case condition of maximum input voltage and during particular
transients, that boot-to-phase voltage overcomes the absolute maximum ratings also
causing device failures. It is then suggested in this cases to limit this extra-charge by adding
a small resistor in series to the bootstrap diode (RD in Figure 1).
Figure 9.
Drivers turn-on and turn-off paths
LS DRIVER
LS MOSFET
HS DRIVER
VCC
HS MOSFET
BOOT
CGD
RGATE
CGD
RINT
RGATE
LGATE
UGATE
CGS
CDS
GND
18/34
RINT
RPHASE
PHASE
Doc ID 12933 Rev 4
CGS
CDS
L6727
9.4
Application details
Embedding L6727-based VRs
When embedding the VR into the application, additional care must be taken since the whole
VR is a switching DC/DC regulator and the most common system in which it has to work is a
digital system such as MB or similar. In fact, latest MBs have become faster and more
powerful: high speed data busses are more and more common and switching-induced noise
produced by the VR can affect data integrity if additional layout guidelines are not followed.
Few easy points must be considered mainly when routing traces in which switching high
currents flow (switching high currents cause voltage spikes across the stray inductance of
the traces causing noise that can affect the near traces):
When reproducing high current path on internal layers, keep all layers the same size in order
to avoid "surrounding" effects that increase noise coupling.
Keep safe guard distance between high current switching VR traces and data busses,
especially if high-speed data busses, to minimize noise coupling.
Keep safe guard distance or filter properly when routing bias traces for I/O sub-systems that
must walk near the VR.
Possible causes of noise can be located in the PHASE connections, MOSFETs gate drive
and Input voltage path (from input bulk capacitors and HS drain). Also GND connection
must be considered if not insisting on a power ground plane. These connections must be
carefully kept far away from noise-sensitive data busses.
Since the generated noise is mainly due to the switching activity of the VR, noise emissions
depend on how fast the current switches. To reduce noise emission levels, it is also possible,
in addition to the previous guidelines, to reduce the current slope and thus to increase the
switching times: this will cause, as a consequence of the higher switching time, an increase
in switching losses that must be considered in the thermal design of the system.
Doc ID 12933 Rev 4
19/34
Application information
L6727
10
Application information
10.1
Output inductor
Inductor value is defined by a compromise between dynamic response, ripple, efficiency,
cost and size. Usually, inductance is calculated to maintain inductor ripple current (ΔIL)
between 20 % and 30 % of maximum output current. Given the switching frequency (FSW),
the input voltage (VIN), the output voltage (VOUT) and the desired ripple current (ΔIL),
inductance can be calculated as follows:
V IN – V OUT V OUT
L = ------------------------------ ⋅ -------------F SW ⋅ ΔI L
V IN
Figure 1 shows the ripple current vs. the output voltage for different inductance, with
VIN = 5 V and VIN = 12 V.
Increasing inductance reduces inductor ripple current (and output voltage ripple
accordingly) but, at the same time, increases the converter response time to load transients.
Higher inductance means that the inductor needs more time to change its current from initial
to final value. Until the inductor has not finished its charging, the additional output current is
supplied by output capacitors. Minimizing the response time lead to minimize the output
capacitance required. If the compensation network is designed with high bandwidth, during
an heavy load transient the device is able to saturate duty cycle (0 % or 80 %). When this
condition is reached, the response time is limited only by the time required to charge the
inductor.
Figure 10. Inductor current ripple vs output voltage
20/34
Doc ID 12933 Rev 4
L6727
10.2
Application information
Output capacitors
Output capacitors choice depends on the application constraints in point of output voltage
ripple and output voltage deviation during a load transient.
During steady-state conditions, the output voltage ripple is influenced by ESR and
capacitance of the output capacitors as follows:
ΔV OUT_ESR = ΔI L ⋅ ESR
1
ΔV OUT_C = ΔI L ⋅ --------------------------------------8 ⋅ C OUT ⋅ F SW
Where ΔIL is the inductor current ripple. These contribution are not in phase, so total ripple
will be lower than the sum of their moduli. Even ESL and board parasitic inductance can
contribute significantly to output ripple.
During a load variation, the output capacitors supply to the load the additional current or
absorb the current in excess delivered by the inductor until converter reaction is completed.
In fact, even if the controller react immediately to the load transient saturating the duty cycle
to 80 % or 0 %, the current slew rate is limited by the inductance. At first approximation,
output voltage drop, based on ESR and capacitor charge/discharge and considering an
ideal load-step, can be estimated as follows:
ΔV OUT_ESR = ΔI OUT ⋅ ESR
2
L ⋅ ΔI OUT
ΔV OUT_C = ------------------------------------2 ⋅ C OUT ⋅ ΔV L
Where ΔVL is the voltage applied to the inductor during the transient ( D MAX ⋅ VIN – V OUT for
the load appliance or VOUT for the load removal).
MLCC capacitors typically have low ESR to minimize the ripple but also have low
capacitance that do not minimize the capacitive voltage deviation during load transient. On
the contrary, electrolytic capacitors usually have higher capacitance to minimize capacitive
voltage deviation during load transient, but also higher ESR value resulting in higher ripple
voltage and resistive voltage drop. For these reasons, a mix between electrolytic and MLCC
capacitor is usually suggested to minimize ripple as well as reducing voltage deviation in
dynamic conditions.
10.3
Input capacitors
The input capacitor bank is designed mainly to stand input rms current, which depends on
output current (IOUT) and duty-cycle (D) for the regulation as follows:
I rms = I OUT ⋅ D ⋅ ( 1 – D )
The equation reaches its maximum value, IOUT/2, when D = 0.5. Losses depend on input
capacitor ESR:
P = ESR ⋅ Irms
2
Doc ID 12933 Rev 4
21/34
20 A demonstration board
11
L6727
20 A demonstration board
L6727 demonstration board realizes on a four-layer PCB a step-down DC/DC converter and
shows the operation of the device in a general purpose application. Input voltage can range
from 5 V to 12 V bus (when VCC > 5 V, R6 need to be removed). Output voltage is
programmed to 1.25 V. The voltage regulator can deliver up to 20 A output current. The
switching frequency is 300 kHz.
Figure 11. 20 A demonstration board (left) and components placement (right)
Figure 12. 20 A demonstration board top (left) and bottom (right) layers
22/34
Doc ID 12933 Rev 4
L6727
20 A demonstration board
Figure 13. 20 A demonstration board inner layers
Doc ID 12933 Rev 4
23/34
Doc ID 12933 Rev 4
R6
12k
R18
NC
LGATE
GND
UGATE
BOOT
0
GNDCC
VCC
0
4
3
2
1
C35
33k
R16
0
33pF
10nF
0
R12
NC
0
R8
VCC
FB
COMP
PHASE
L6726A/27
GND
VCC
C24
LGATE
GND
UGATE
BOOT
U1
R7
COMP
GND
VCC
GNDIN1
5
6
7
8
FB
2.2
FB
0
R13
3.9k
0
UGATE
3.3
R2
C2
1800uF
NC
R14
2.2k
R9
NC
C36
LGATE
C3
NC
R15
R5
R3
C10
BOOT
100nF
0
LGATE
PHASE
UGATE
0
R17
PHASE
COMP
0
C38
D1
1N4148
VCC_PIN
VCC
3.3
1uF
R1
C14
1uF
0
C1
1800uF
0
1
HSG 1
LSG1
NC
0
2.2
NC
C4
NC
0
C5
PHASE
VIN1
C37
R10
NC
0
NC
0
R11
LSG2
Q5
STD90NH2LL 1
Q4
STD55NH2LL
0
Q6
NC
0
1
L2
2
T60-18 6Ts
C23
6.8nF
R4
1.8
0
ᤡ
C15
0
2200uF
C25
0
NC
C13
4.7uF
HSG 4
Q1
NC
0
C12
C11
0
4.7uF
4.7uF
0
0
NC
C9
NC
C8
VIN_POWER
0
0
NC
C7
NC
C6
2
GNDIN_POWER
VCC_PIN
2
3
2
C27
0
0
NC
C26
NC
0
Q2
NC
0
C18
0
NC
C29
OUT
0
2200uF
C28
NC
ᤢ
OUT
LSG1 4
C17
NC
0
NC
C16
5
6
7
8
1
2
3
PHASE
COMP
C19
0
NC
C30
0
NC
0
NC
C31
0
NC
C20
PHASE 1
PHASE
FB
HSD
3
GND
3
5
6
7
8
1
2
3
24/34
HSD
Q3
NC
2
0
NC
C32
0
NC
C21
0
NC
C33
0
NC
C22
LSG2 4
NC
L1
OUT
C34
0
NC
0
GNDOUT1
GNDOUT
VOUT1
VOUT
GND
OUT
PHASE
5
6
7
8
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R
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QW
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I
L
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U
L
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G
GI
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2
3
VIN_POWER
20 A demonstration board
L6727
Figure 14. 20 A demonstration board schematic
V
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R
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D
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5
5
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L6727
20 A demonstration board
Table 6.
20 A demonstration board - bill of material
Qty
Reference
Description
Package
Capacitors
2
C1, C2
Electrolytic Cap 1800 μF 16 V
Nippon chemi-con KZJ or KZG
1
C10
MLCC, 100 nF, 25 V, X7R
SMD0603
3
C11 to C13
MLCC, 4.7 μF, 16 V, X5R
Murata GRM31CR61C475MA01
SMD1206
2
C14, C38
MLCC, 1 μF, 16 V, X7R
SMD0805
2
C18, C25
Electrolytic Cap 2200 μF 6.3 V
Nippon chemi-con KZJ or KZG
1
C23
MLCC, 6.8 nF, X7R
1
C24
MLCC, 10 nF, X7R
1
C35
MLCC, 33 pF, X7R
Radial 10 x 25 mm
Radial 10 x 20 mm
SMD0603
Resistors
2
R1, R2
Resistor, 3R3, 1/16 W, 1 %
1
R17
Resistor, 2R2, 1/16 W, 1 %
2
R5, R16
Resistor, 0R, 1/8 W, 1 %
1
R3
Resistor, 2R2, 1/8 W, 1 %
1
R4
Resistor, 1R8, 1/8 W, 1 %
2
R11, R8
Resistor, 0R, 1/16 W, 1 %
1
R9
Resistor, 2K2, 1/16 W, 1 %
1
R13
Resistor, 3K9, 1/16 W, 1 %
1
R7
Resistor, 33K, 1/16 W, 1 %
1
R6
Resistor, 12K, 1/16 W, 1 %
L1
Inductor, 1.25 μH, T60-18, 6Turns
Easymagnet AP106019006P-1R1M
SMD0603
SMD0805
SMD0603
Inductor
1
na
Active components
1
D1
Diode, 1N4148 or BAT54
1
Q5
STD55NH2LL
1
Q6
STD90NH2LL
1
U1
Controller, L6727
SOT23
DPACK
Doc ID 12933 Rev 4
SO8
25/34
20 A demonstration board
11.1
Board description
11.1.1
Power input (VIN)
L6727
This is the input voltage for the power conversion. The high-side MOSFET drain is
connected to this input. Supply must be compliant with VIN recommended operating
conditions and capacitors rating.
If VIN voltage is compliant also to VCC range listed in recommended operating conditions, it
can supply also the device through R16 resistor. When VCC > 5 V, R6 need to be removed.
11.1.2
Power output (VOUT)
This is the output voltage of the power conversion. The output voltage is programmed to
1.25 V. It can be changed by replacing R13. R6 allows to adjust OCP threshold when
VCC = 5 V.
11.1.3
IC additional supply (VCC)
The controller can be supplied separately from the power conversion through VCC input. In
this case, to separate VCC from VIN, R16 resistor must be removed. When VCC > 5 V, R6
need to be removed.
11.1.4
Test points
The following test points are provided to allow easy probing of important signals:
11.1.5
–
COMP: output of the error amplifier;
–
FB: inverting input of the error amplifier;
–
PH: Phase pin of the device;
–
LG: Low-Side gate pin of the device;
–
UG: High-Side gate pin of the device.
Demonstration board efficiency
Figure 15. 20 A demonstration board efficiency
26/34
Doc ID 12933 Rev 4
L6727
12
5 A demonstration board
5 A demonstration board
L6727 demonstration board realizes on a two-layer PCB a step-down DC/DC converter and
shows the operation of the device in a general-purpose low-current application. Input
voltage can range from 5 V to 12 V bus. Output voltage is programmed at 1.25 V. The
application can deliver an output current in excess of 5 A. The switching frequency is 300
kHz.
Figure 16. 5 A demonstration board (left) and components placement (right)
Figure 17. 5 A demonstration board top (left) and bottom (right) layers
Doc ID 12933 Rev 4
27/34
R18
NC
LGATE
0
ᤡ
2
UGATE
4
3
1
GNDIN1
L6727
VCC
FB
COMP
PHASE
U1
GND
VCC
ᤢ
5
6
7
8
R16
0
Doc ID 12933 Rev 4
U
H
O
O
N
UR
U
RW
Q
ZR
W
HF
1
H
QK
W
R
LU
D
W
D
H
VQ
Q
HH
SF
D
PO
RS
&
0
0
R8
C35
220pF
R10
NC
0
R13
3.9K
R14
15
C36
6.8nF
3.3
R5
0
LSG1
HSG1
2
4
1
0
7 8
3
VIN_POWER
U5A
STS9D8NH3LL
U5B
STS9D8NH3LL
HSD
5 6
0
L3
NC
L2
2.2uH
C23
6.8nF
R4
1.8
2
2
1
1
0
ᤡ
C12
10uF
ᤡ
ᤡ
C29
NC
0
C39
22uF
OUT
0
ᤡ
0
ᤢ
C18
NC
OUT
0
OUT
C40
NC
V
U
R
W
L
F
D
S
D
F
F
L
P
D
U
H
F
2.2k
R9
LGATE
LGATE
R17
0
PHASE
R3
C10
100nF
BOOT
C51
10uF
ᤢ
0
ᤢ
0
C29A
NC
ᤢ
C30
330uF
OUT
W
Q
L
U
S
W
R
R
I
O
D
X
G
4.7k
R7
FB
UGATE
PHASE PIN
PHASE
UGATE
3.3
V
U
R
W
L
F
D
S
D
F
P
X
O
D
W
Q
D
7
COMP
R1
3.3
VCC
0
R2
U
R
W
L
F
D
S
D
F
F
L
W
\
O
R
U
W
F
H
O
(
C24
68nF
VCC_PIN
FB
COMP
PHASE PIN
C38
1uF
D1
BAT54
W
Q
L
U
S
W
R
R
I
O
D
X
G
C14
1uF
LGATE/OC
GND
UGATE
BOOT
VCC
GND
BOOT
0
GNDCC
VCC
0
GNDIN_POWER
V
U
R
W
L
F
D
S
D
F
F
L
P
D
U
H
F
GND
VIN1
L6727
28/34
W
Q
L
U
S
W
R
R
I
O
D
X
G
COMP
V
R
P
6
+
U
D
H
Q
H
F
D
O
S
FB
VIN_POWER
VOUT
0
GNDOUT1
GNDOUT
VOUT1
5 A demonstration board
L6727
Figure 18. 5 A demonstration board schematic
OUT
L6727
5 A demonstration board
Table 7.
5 A demonstration board - bill of material
Qty
Reference
Description
Package
Capacitors
2
C12, C51
10 μF, 25 V, X5R
Murata GRM31CR61E106KA12
SMD1206
1
C10
MLCC, 100 nF, 25 V, X7R
SMD0603
2
C14, C38
MLCC, 1 μF, 16 V, X7R
SMD0805
1
C39
MLCC, 22 μF, 6.3 V, X5R
Murata GRM31CR60J226ME19
SMD1206
1
C30
330 μF, 6.3 V, 9 mΩ
Sanyo 6TPF330M9L
SMD7343
2
C23, C36
MLCC, 6.8 nF, X7R
1
C24
MLCC, 68 nF, X7R
1
C35
MLCC, 220 pF, X7R
1
R4
Resistor, 1R8, 1/8 W, 1 %
4
R3, R5, R8, R16
Resistor, 0R, 1/16 W, 1 %
3
R1, R2, R17
Resistor, 3R3, 1/16 W, 1 %
1
R14
Resistor, 15R, 1/16 W, 1 %
1
R9
Resistor, 2K2, 1/16 W, 1 %
1
R13
Resistor, 3K9, 1/16 W, 1 %
1
R7
Resistor, 4K7, 1/16 W, 1 %
L1
Inductor, 2.20 μH,
Wurth 744324220LF
SMD0603
Resistors
SMD0805
SMD0603
SMD0603
Inductor
1
na
Active Components
1
D1
Diode, BAT54
1
Q5
Mosfet, STS9D8NH3LL
SO8
1
U1
Controller, L6727
SO8
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5 A demonstration board
12.1
Board description
12.1.1
Power input (VIN)
L6727
This is the input voltage for the power conversion. The high-side MOSFET drain is
connected to this input. Supply must be compliant with VIN recommended operating
conditions and capacitors rating.
If VIN voltage is compliant also to VCC range listed in recommended operating conditions, it
can supply also the device through R16 resistor.
12.1.2
Power iutput (VOUT)
This is the output voltage of the power conversion. The output voltage is programmed to
1.25 V. It can be changed by replacing R13.
12.1.3
IC additional supply (VCC)
The controller can be supplied separately from the power conversion through VCC input. In
this case, to separate VCC from VIN, R16 resistor must be removed.
12.1.4
Test points
The following test points are provided to allow easy probing of important signals:
12.1.5
–
COMP: output of the error amplifier;
–
FB: inverting input of the error amplifier;
–
PH: Phase pin of the device;
–
LG: Low-Side gate pin of the device;
–
UG: High-Side gate pin of the device.
Demonstration board efficiency
Figure 19. 5 A demonstration board efficiency
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L6727
13
Package mechanical data
Package mechanical data
In order to meet environmental requirements, ST offers these devices in different grades of
ECOPACK® packages, depending on their level of environmental compliance. ECOPACK®
specifications, grade definitions and product status are available at: www.st.com.
ECOPACK is an ST trademark.
Table 8.
SO-8 mechanical data
mm.
inch
Dim.
Min
Typ
Max
Min
Typ
Max
A
1.35
1.75
0.053
0.069
A1
0.10
0.25
0.004
0.010
A2
1.10
1.65
0.043
0.065
B
0.33
0.51
0.013
0.020
C
0.19
0.25
0.007
0.010
D (1)
4.80
5.00
0.189
0.197
E
3.80
4.00
0.15
0.157
e
1.27
0.050
H
5.80
6.20
0.228
0.244
h
0.25
0.50
0.010
0.020
L
0.40
1.27
0.016
0.050
k
ddd
0° (min.), 8° (max.)
0.10
0.004
1. D and F does not include mold flash or protrusions. Mold flash or potrusions shall not exceed 0.15mm
(.006inch) per side.
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Package mechanical data
L6727
Figure 20. Package dimensions
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14
Revision history
Revision history
Table 9.
Revision history
Date
Revision
04-Dec-2006
1
Initial release.
28-Feb-2007
2
Updated VOCTH values in Table 5 on page 7
06-Jun-2007
3
Updated Figure 1: Typical application circuit on page 4,
Table 3 and Table 4 on page 6
4
Added Section 10: Application information on page 20, Section 11:
20 A demonstration board on page 22, Section 12: 5 A
demonstration board on page 27
Updated: Table 5 on page 7
23-Mar-2010
Changes
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L6727
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