ONSEMI NCP3012DTBR2G

NCP3012
Synchronous PWM Controller
The NCP3012 is a PWM device designed to operate from a wide
input range and is capable of producing an output voltage as low as
0.8 V. The NCP3012 provides integrated gate drivers and an internally
set 75 kHz oscillator. The NCP3012 has an externally compensated
transconductance error amplifier with an internally fixed soft−start.
The NCP3012 incorporates output voltage monitoring with a Power
Good pin to indicate that the system is in regulation. The dual function
SYNC pin synchronizes the device to a higher frequency (Slave
Mode) or outputs a 180° out−of−phase clock signal to drive another
NCP3012 (Master Mode). Protection features include lossless current
limit and short circuit protection, output overvoltage and undervoltage
protection, and input undervoltage lockout. The NCP3012 is available
in a 14−pin TSSOP package.
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14
1
TSSOP−14
DT SUFFIX
CASE 948G
Features
•
•
•
•
•
•
•
•
•
•
•
Input Voltage Range from 4.7 V to 28 V
75 kHz Operation
0.8 V $1.0% Reference Voltage
Buffered External +1.25 V Reference
Current Limit and Short Circuit Protection
Power Good
Enable/Disable Pin
Input Undervoltage Lockout
External Synchronization
Output Overvoltage and Undervoltage Protection
This is a Pb−Free Device
MARKING DIAGRAM
14
3012
ALYWG
G
1
3012= Device Code
A
= Assembly Location
L
= Wafer Lot
Y
= Year
W = Work Week
G
= Pb−Free Package
(Note: Microdot may be in either location)
Typical Applications
• Set Top Box
• Power Modules
• ASIC / DSP Power Supply
PIN CONNECTIONS
VREF
EN
NC
SYNC
VIN
CBST
CIN
VCC
BST
LO
VOUT
VSW
PG
Q2
LSDR
VREF
RREF
GND
COMP
CC2
GND
(TOP VIEW)
RFB2
ORDERING INFORMATION
FB
Device
© Semiconductor Components Industries, LLC, 2010
Package
Shipping†
NCP3012DTBR2G TSSOP−14 2500 / Tape & Reel
(Pb−Free)
C C1
†For information on tape and reel specifications,
including part orientation and tape sizes, please
refer to our Tape and Reel Packaging Specifications
Brochure, BRD8011/D.
Figure 1. Typical Application Circuit
May, 2010 − Rev. 0
LSDR
CO
RC
CREF
NC
COMP
FB
RFB1
R ISET
SYNC
HSDR
VSW
PG
Q1
HSDR
EN
VCC
BST
1
Publication Order Number:
NCP3012/D
NCP3012
VCC
INTERNAL BIAS
EN
PG
BST
POR/STARTUP
ENABLE/
POWER GOOD
LOGIC
VC
THERMAL SD
BOOST
CLAMP
SYNC
CLK/
DMAX/
SOFT
START
OSCILLATOR
VREF
GATE
DRIVE
LOGIC
RAMP
1.25 V
REFERENCE
1.5 V
LEVEL
SHIFT
HSDR
VCC
VSW
CURRENT
LIMIT
SAMPLE &
HOLD
ISET
+
−
COMP
REF
OTA
VC
LSDR
PWM
COMP
FB
+
−
+
−
OOV
OUV
Figure 2. NCP3012 Block Diagram
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2
BST_CHRG
GND
NCP3012
PIN FUNCTION DESCRIPTION
Pin
Pin Name
1
VREF
Description
2
EN
The EN pin is the enable/disable input. A logic high on this pin enables the device. This pin has also an internal
current source pull up. A 10 kW resistor should be connected in series with this pin if VEN is externally biased
from a separate supply.
3
NC
Not Connected
4
SYNC
5
PG
6
COMP
7
FB
8
GND
Ground Pin
9
LSDR
The LSDR pin is connected to the output of the low side driver which connects to the gate of the low side
N−FET. It is also used to set the threshold of the current limit circuit (ISET) by connecting a resistor from LSDR
to GND.
10
NC
11
VSW
The VSW pin is the return path for the high side driver. It is also used in conjunction with the VCC pin to sense
current in the high side MOSFET.
12
HSDR
The HSDR pin is connected to the output of the high side driver which connects to the gate of the high side
N−FET.
13
BST
The BST pin is the supply rail for the gate drivers. A capacitor must be connected between this pin and the
VSW pin.
14
VCC
The VCC pin is the main voltage supply input. It is also used in conjunction with the VSW pin to sense current
in the high side MOSFET.
The VREF pin is the output for a 1.25 V reference (1 mA max). A 100 kW resistor in parallel with a 1 mF
ceramic capacitor must be connected from this pin to GND to ensure external reference stability.
The dual function SYNC pin synchronizes the device to a higher frequency (Slave Mode). Alternately, it outputs
an 85 kHz clock signal with 180° of phase shift (Master Mode). Connect a 60 kW resistor from SYNC to GND
to enable Master Mode. No resistor is required for Slave Mode.
The Power Good pin is an open drain output that is low when the regulated output voltage is beyond the
“Power Good” upper and lower thresholds. Otherwise, it is a high impedance pin.
The COMP pin connects to the output of the Operational Transconductance Amplifier (OTA) and the positive
terminal of the PWM comparator. This pin is used in conjunction with the FB pin to compensate the voltage
mode control feedback loop.
The FB pin is connected to the inverting input of the OTA. This pin is used in conjunction with the COMP pin to
compensate the voltage mode control feedback loop.
Not Connected
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NCP3012
ABSOLUTE MAXIMUM RATINGS (measured vs. GND pin 8, unless otherwise noted)
Rating
Symbol
VMAX
VMIN
Unit
BST
45
−0.3
V
BST−VSW
13.2
−0.3
V
COMP
COMP
5.5
−0.3
V
Enable
EN
5.5
−0.3
V
Feedback
FB
5.5
−0.3
V
High Side Drive Boost Pin
Boost to VSW differential voltage
High−Side Driver Output
HSDR
40
−0.3
V
Low−Side Driver Output
LSDR
13.2
−0.3
V
PG
5.5
−0.3
V
SYNC
5.5
−0.3
V
VCC
40
−0.3
V
VREF
5.5
−0.3
V
Switch Node Voltage
VSW
40
−0.6
Maximum Average Current
VCC, BST, HSDRV, LSDRV, VSW, GND
REF
EN
SYNC
PG
Imax
Power Good
Synchronization
Main Supply Voltage Input
External Reference
Operating Junction Temperature Range (Note 1)
130
7.1
2.5
11
4
V
mA
TJ
−40 to +140
°C
TJ(MAX)
+150
°C
Storage Temperature Range
Tstg
−55 to +150
°C
Thermal Characteristics (Note 2)
TSSOP−14 Plastic Package
Thermal Resistance Junction−to−Air
RqJA
190
°C/W
RF
260 Peak
°C
Maximum Junction Temperature
Lead Temperature Soldering (10 sec): Reflow (SMD styles only) Pb−Free
(Note 3)
Stresses exceeding Maximum Ratings may damage the device. Maximum Ratings are stress ratings only. Functional operation above the
Recommended Operating Conditions is not implied. Extended exposure to stresses above the Recommended Operating Conditions may affect
device reliability.
1. The maximum package power dissipation limit must not be exceeded.
PD +
T J(max) * T A
R qJA
2. When mounted on minimum recommended FR−4 or G−10 board
3. 60−180 seconds minimum above 237°C.
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NCP3012
ELECTRICAL CHARACTERISTICS (−40°C < TJ < +125°C, VCC = 12 V, for min/max values unless otherwise noted)
Characteristic
Conditions
Min
−
4.7
Max
Unit
28
V
EN = 0 VCC = 12 V
−
2.5
4.0
mA
VCC Supply Current
VFB = 0.75 V, Switching, VCC = 4.7 V
−
5.8
8.0
mA
VCC Supply Current
VFB = 0.75 V, Switching, VCC = 28 V
−
6.0
12
mA
UVLO Rising Threshold
VCC Rising Edge
3.8
4.3
4.7
V
UVLO Falling Threshold
VCC Falling Edge
3.5
4.0
4.3
V
Input Voltage Range
Typ
SUPPLY CURRENT
Quiescent Supply Current
UNDER VOLTAGE LOCKOUT
OSCILLATOR
Oscillator Frequency
Ramp−Amplitude Voltage
TJ = +25°C, 4.7 V v VCC v 28 V
65
75
85
kHz
TJ = −40°C to +125°C, 4.7 V v VCC v 28 V
62
75
88
kHz
Vpeak − Valley
−
1.5
−
V
0.44
0.8
0.96
V
Ramp Valley Voltage
PWM
Minimum Duty Cycle
−
7
−
%
Maximum Duty Cycle
82
86
−
%
VFB = VCOMP
−
14
−
ms
IREF = 1 mA
1.14
1.25
1.35
V
VREF Line Regulation
VCC = 4.7 V − 28 V
−1
−
+1
%
VREF Load Regulation
IREF = 0 mA to 1.5 mA
−2
−0.2
+2
%
VREF = 0 V
4.5
5.7
7.0
mA
Enable Threshold High
−
−
3.4
V
Enable Threshold Low
1.0
−
−
V
Enable Source Current
20
50
90
mA
Soft Start Ramp Time
EXTERNAL VOLTAGE REFERENCE
VREF Voltage
Short Circuit Output Current
ENABLE
POWER GOOD
Power Good High Threshold
VCC = 12 V
0.72
0.89
1.06
V
Power Good Low Threshold
VCC = 12 V
0.65
0.71
0.75
V
VCC = 12 V, IPG = 4 mA
0.13
0.22
0.35
V
−
−
2.0
V
−
5.0
−
V
−
90
−
mV
−
200
−
°
−
1.6
−
mA
Master Threshold Current
5.0
14.4
25
mA
Master Frequency
70
85
100
kHz
Power Good Low Voltage
SYNC
SYNC Input High Threshold
SYNC Output High
10 mA load
SYNC Output Low
Phase Delay
(Note 4)
SYNC Drive Current (Sourcing)
4.
5.
6.
7.
Guaranteed by design.
The voltage sensed across the high side MOSFET during conduction.
This assumes 100 pF capacitance to ground on the COMP Pin and a typical internal Ro of > 10 MW.
This is not a protection feature.
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NCP3012
ELECTRICAL CHARACTERISTICS (−40°C < TJ < +125°C, VCC = 12 V, for min/max values unless otherwise noted)
Characteristic
Conditions
Min
Typ
Max
Unit
0.9
1.33
1.9
mS
−
70
−
dB
45
45
70
70
100
100
mA
mA
ERROR AMPLIFIER (GM)
Transconductance
Open Loop dc Gain
(Notes 4 and 6)
Output Source Current
Output Sink Current
FB Input Bias Current
−
0.5
500
nA
TJ = 25 C
0.792
0.8
0.808
V
−40°C < TJ < +125°C,
4.7 V < VIN < 28 V
0.788
0.8
0.812
V
COMP High Voltage
VFB = 0.75 V
4.0
4.4
5.0
V
COMP Low Voltage
VFB = 0.85 V
−
60
−
mV
Feedback Voltage
OUTPUT VOLTAGE FAULTS
Feedback OOV Threshold
0.8
1.0
1.1
V
Feedback OUV Threshold
0.55
0.59
0.65
V
OVER CURRENT
7.0
14
18
mA
RSET = 22.2 kW
140
240
360
mV
VCC = 8 V and VBST = 7.5 V
VSW = GND, 100 mA out of HSDR pin
4.0
10.5
20
W
VCC = 8 V and VBST = 7.5 V
VSW = GND, 100 mA into HSDR pin
2.0
5.0
11.5
W
VCC = 8 V and VBST = 7.5 V
VSW = GND, 100 mA out of LSDR pin
3.0
8.9
16
W
VCC = 8 V and VBST = 7.5 V
VSW = GND, 100 mA into LSDR pin
1.0
2.8
6.0
W
HSDRV falling to LSDRV Rising
Delay
VCC and VBST = 8 V
50
85
110
ns
LSDRV Falling to HSDRV Rising
Delay
VCC and VBST = 8 V
60
85
120
ns
VIN = 12 V, VSW = GND, VCOMP = 1.3 V
5.5
7.5
9.6
V
Thermal Shutdown
(Notes 4 and 7)
−
150
−
°C
Hysteresis
(Notes 4 and 7)
−
15
−
°C
ISET Source Current
Current Limit Set Voltage (Note 5)
GATE DRIVERS AND BOOST CLAMP
HSDRV Pullup Resistance
HSDRV Pulldown Resistance
LSDRV Pullup Resistance
LSDRV Pulldown Resistance
Boost Clamp Voltage
THERMAL SHUTDOWN
4.
5.
6.
7.
Guaranteed by design.
The voltage sensed across the high side MOSFET during conduction.
This assumes 100 pF capacitance to ground on the COMP Pin and a typical internal Ro of > 10 MW.
This is not a protection feature.
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NCP3012
TYPICAL PERFORMANCE CHARACTERISTICS
806
90
804
85
80
Vin = 12 V, 28 V
800
798
fSW (kHz)
VFB (mV)
802
Vin = 5 V
Vin = 12 V, 28 V
75
Vin = 5 V
70
796
65
794
792
−40 −25 −10
5
20
35
50
65
80
60
−40 −25 −10
95 110 125
5
TEMPERATURE (°C)
20
35
Figure 3. Feedback Reference Voltage vs. Input
Voltage and Temperature
65
80
95 110 125
Figure 4. Switching Frequency vs. Input Voltage
and Temperature
3.0
7.0
2.8
6.5
Vin = 28 V
2.6
ICC, DISABLED (mA)
ICC, SWITCHING (mA)
50
TEMPERATURE (°C)
Vin = 28 V
6.0
5.5
Vin = 12 V
5.0
4.5
Vin = 5 V
4.0
−40 −25 −10
5
20
35
50
2.4
2.2
Vin = 12 V
Vin = 5 V
2.0
1.8
1.6
1.4
1.2
65
80
1.0
−40 −25 −10
95 110 125
5
TEMPERATURE (°C)
20
35
50
65
80
95 110 125
TEMPERATURE (°C)
Figure 5. Supply Current vs. Input Voltage and
Temperature
Figure 6. Supply Current (Disabled) vs. Input
Voltage and Temperature
1.39
4.4
1.375
Vin = 5 V
1.36
4.3
UVLO Rising Threshold
1.33
1.315
UVLO (V)
gm (mS)
1.345
Vin = 12 V, 28 V
1.30
4.2
4.1
1.285
4.0
1.27
UVLO Falling Threshold
1.255
1.24
−40 −25 −10
5
20
35
50
65
80
3.9
−40 −25 −10
95 110 125
TEMPERATURE (°C)
5
20
35
50
65
80
95 110 125
TEMPERATURE (°C)
Figure 8. Input Undervoltage Lockout vs.
Temperature
Figure 7. Transconductance vs. Input Voltage and
Temperature
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NCP3012
TYPICAL PERFORMANCE CHARACTERISTICS
1100
350
300
PG_Upper, Vin = 5 − 28 V
900
800
PG_Lower, Vin = 5 − 28 V
700
275
250
Vin = 5, 12, 28 V
225
200
OUV, Vin = 5 − 28 V
600
IPG = 4 mA
325
1000
VPG (mV)
THRESHOLD VOLTAGE (mV)
OOV, Vin = 5 − 28 V
175
500
−40 −25 −10
20
5
35
50
65
80
150
−40 −25 −10
95 110 125
5
TEMPERATURE (°C)
Rising Threshold
Vin = 12 V, 28 V
60
Vin = 5, 12, 28 V
55
2.5
IEN (mA)
VEN (V)
95 110 125
65
Vin = 5 V
2.75
2.25
Falling Threshold
1.75
Vin = 12 V, 28 V
Vin = 5 V
1.0
−40 −25 −10
50
45
40
1.5
35
5
20
35
50
65
80
30
−40 −25 −10
95 110 125
5
TEMPERATURE (°C)
35
50
65
80
95 110 125
Figure 12. Enable Pullup Current vs. Input Voltage
and Temperature
1000
950
2.0
VALLEY VOLTAGE (mV)
1.8
Vin = 12 V, 28 V
1.6
Vin = 5 V
1.4
1.2
1.0
−40 −25 −10
20
TEMPERATURE (°C)
Figure 11. Enable Thresold vs. Input Voltage and
Temperature
VSYNC (V)
80
70
3.0
1.25
65
50
Figure 10. Power Good Output Low Voltage vs.
Input Voltage and Temperature
3.5
2.0
35
TEMPERATURE (°C)
Figure 9. Output Voltage Thresholds vs. Input
Voltage and Temperature
3.25
20
5
20
35
50
65
80
95 110 125
900
850
800
750
700
650
600
Vin = 5 − 28 V
550
500
450
400
−40 −25 −10
5
20
35
50
65
80
95 110 125
TEMPERATURE (°C)
TEMPERATURE (°C)
Figure 14. Valley Voltage vs. Input Voltage and
Temperature
Figure 13. SYNC Threshold vs. Input Voltage and
Temperature
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NCP3012
TYPICAL PERFORMANCE CHARACTERISTICS
1.26
1.0
0.8
1.255
1.245
VREFE_load−reg (%)
VREFE (V)
1.25
0.6
Vin = 5 V
Vin = 12 V, 28 V
1.24
0.4
0.2
Vin = 5 V
0
−0.2
−0.4
Vin = 12 V, 28 V
−0.6
1.235
−0.8
1.23
−40 −25 −10
5
20
35
50
65
80
95 110 125
−1.0
−40 −25 −10
5
20
35
50
65
80
95 110 125
TEMPERATURE (°C)
TEMPERATURE (°C)
Figure 15. External Reference Voltage vs. Input
Voltage and Temperature
Figure 16. External Reference Voltage vs. Input
Voltage and Temperature
14.0
ISET (mA)
13.8
13.6
Vin = 12 V, 28 V
13.4
Vin = 5 V
13.2
13.0
−40 −25 −10
5
20
35
50
65
80
95 110 125
TEMPERATURE (°C)
Figure 17. Current Limit Set Current vs.
Temperature
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NCP3012
DETAILED DESCRIPTION
OVERVIEW
threshold. The device remains in Standby if enable is not
asserted following the 50 ms time period.
The NCP3012 operates as a 75 kHz, voltage−mode,
pulse−width−modulated, (PWM) synchronous buck
converter. It drives high−side and low−side N−channel
power MOSFETs. The NCP3012 incorporates an internal
boost circuit consisting of a boost Clamp and boost diode to
provide supply voltage for the high side MOSFET Gate
driver. The NCP3012 also integrates several protection
features including input undervoltage lockout (UVLO),
output undervoltage (OUV), output overvoltage (OOV),
adjustable high−side current limit (ISET and ILIM), and
thermal shutdown (TSD). The NCP3012 includes a
Power Good (PG) open drain output which flags out of
regulation conditions.
The operational transconductance amplifier (OTA)
provides a high gain error signal which is compared to the
internal ramp signal using the PWM comparator. This
results in a voltage mode PWM feedback stage. The PWM
signal is sent to the internal gate drivers to modulate
MOSFET on and off times. The gate driver stage
incorporates symmetrical fixed non−overlap time between
the high−side and low−side MOSFET gate drives.
The NCP3012 has a dual function Master/Slave SYNC
pin In Slave mode, the NCP3012 synchronizes to an external
clock signal. In Master mode, the NCP3012 can output a
phase shifted clock signal to drive another master slave
equipped power stage to provide a 180° switching
relationship between the power stages. This can help to
reduce the required input filter capacitance in multi−stage
power converters.
The external 1.25 V reference voltage (VREF) is
provided for system level use. It remains active even when
the NCP3012 is disabled.
Enable/Disable
The device has an enable pin (EN) with internal 50 mA
pullup current. This gives the user the option of driving EN
with a push−pull or open−drain/collector enable signal.
When driving EN with an external logic supply a 10 kW
series current limiting resistor must be placed in series with
EN. See Figure 18. The maximum enable threshold is 3.4 V.
If no external drive voltage is available, the internal pullup
can be used to enable the device, and an open drain/collector
input, such as a MOSFET or BJT can be used to disable the
device. A capacitor connected between EN and ground can
be used with the internal pullup current source to provide a
fixed delay to turn−on and turn off. See Equation 1.
V EN
10 kW
DISABLE ENABLE
EN
Enable
Logic
− or−
ENABLE DISABLE
−or−
ENABLE
DISABLE
Figure 18. Enable Circuits: Push−Pull, Open−Drain,
or Open−Collector
POR and UVLO
The device contains an internal Power On Reset (POR)
and input Undervoltage Lockout (UVLO) that inhibits the
internal logic and the output stage from operating until VCC
reaches their respective predefined voltage levels. The
internal logic takes approximately 50 ms to check the SYNC
pin and determine if the device is in Master mode or Slave
mode once the voltage at VCC exceeds the rising UVLO
C EN_DLY +
I PU
T EN_DLY
V EN_TH
CEN_DLY = Delay Capacitance (F)
IPU = Pullup Current
VEN_TH = Enable Input High Threshold Voltage
TEN_DLY = Desired Delay Time
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(eq. 1)
NCP3012
Startup and Shutdown
The soft−stop process begins once the EN pin voltage
goes below the input low threshold. Soft−stop decreases the
internal reference from 0.8 V − 0 V in 32 steps as with
Soft−Start. Soft−Stop finishes with one “last” high side gate
pulse at half the period of the prior pulse. This helps ensure
positive inductor current following turn off at light loads,
which prevents negative output voltage.
Enable low during Soft−Start will result in Soft−Stop
down counting from that step. Likewise, Enable high during
Soft−Stop will result in Soft−Start up counting from that
step.
Once enable is asserted the device begins its startup
process. Closed−loop soft−start begins after a 400 ms delay
wherein the boost capacitor is charged, and the current limit
threshold is set. During the 400 ms delay the OTA output is
set to just below the valley voltage of the internal ramp. This
is done to reduce delays and to ensure a consistent pre
soft−start condition. The device increases the internal
reference from 0 V to 0.8 V in 32 discrete steps while
maintaining closed loop regulation at each step. Some
overshoot may be evident at the start of each step depending
on the voltage loop phase margin and bandwidth. See
Figure 19. The total soft−start time is 14 ms.
0.8 V Output Voltage
25 mV Steps
32 Voltage Steps
Internal Reference Voltage
Internal Ramp
OTA Output
0 .7V
0V
Figure 19. Soft−Start Details
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NCP3012
Master/Slave Synchronization
(Slave Mode) or provide an external clock that is shifted by
180° from the high side switch (Master Mode). The typical
application circuit for this is shown in Figure 20.
The SYNC pin performs two functions. The first function
is to identify if the device is a master or a slave. The second
function is to either synchronize to an external clock
VIN
HSDR
MASTER
VIN
SYNC 2
SYNC 1
HSDR
SLAVE
60kW
Figure 20. Master Slave Typical Application
Upon initial power up, the device determines if it is a
Master or Slave by applying 1.25 V to the SYNC pin and
determining whether the current draw from the pin is greater
than the Master Threshold Current (ISYNCTRIP). If
ISYNCTRIP is exceeded then the device enters master mode.
If the current is less than ISYNCTRIP the device enters slave
mode. Once identified as a Master, the device switching
frequency is increased by 15%. See Equation 2.
R Master +
0−50%
Duty
Cycle
Slave
HSDRV
Master
Detection
0−50%
Duty
Cycle
Hold
Result
Vref = 1.25 V
SYNC1
Voltage
Time > 40 ms
Time > 40 ms
Vref = 1.25 V
SYNC 2
Voltage
40 ms
Slave Pull
Down Turn on
ITRIP = 10 mA
SYNC 1
Current
SYNC 2
Current
Indication
of Master
Indication
of Slave
ISYNC TRIP
RMaster = Master Select Resistor (W)
SYNCref = Sync Reference Voltage (V)
ISYNCTRIP = Master Threshold Current (A)
Master
HSDRV
Pulse
Detect
SYNC ref
0 mA
Input
Voltage
Figure 21. Master Slave Typical Waveforms
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(eq. 2)
NCP3012
the ramp signal. The equation for calculating the remaining
ramp height is shown below:
The master slave identification begins when input voltage
is applied prior to POR. Upon application of input voltage,
the device waits for input pulses for a minimum of 40 ms as
shown in Figure 21. During the pulse detection period if
concurrent edges occur on the SYNC pin from an external
source, the device enters slave mode and skips the master
detection sequence. The device will remain in the detected
state until power is cycled.
V RAMP + VRAMP typ *
Master
Detect
&
Hold
SYNC_out
Figure 22.
75 kHz
100 kHz
[ 1.125 V
(eq. 3)
The output voltage of the buck converter is monitored at
the Feedback pin of the output power stage. Four
comparators are placed on the feedback node of the OTA to
monitor the operating window of the feedback voltage as
shown in Figures 23 and 24. All comparator outputs are
ignored during the soft−start sequence as soft−start is
regulated by the OTA and false trips would be generated.
Further, the Power Good pin is held low until the
comparators are evaluated. After the soft−start period has
ended, if the feedback is below the reference voltage of
comparator 4 (0.6 < VFB), the output is considered
“undervoltage,” the device will initiate a restart, and the
Power Good pin remains low with a 55 W pulldown
resistance. If the voltage at the Feedback pin is between the
reference voltages of comparator 4 and comparator 3 (0.60
< VFB < 0.72), then the output voltage is considered “power
not good low” and the Power Good pin remains low. When
the Feedback pin voltage rises between the reference
voltages of comparator 3 and comparator 2 (0.72 < VFB <
0.88), then the output voltage is considered “Power Good”
and the Power Good pin is released. If the voltage at the
Feedback pin is between the reference voltages of
comparator 2 and comparator 1 (0.88 < VFB < 1.00), the
output voltage is considered “power not good high” and the
power good pin is pulled low with a 55 W pulldown
resistance. Finally, if the feedback voltage is greater than
comparator 1 (1.0 < VFB), the output voltage is considered
“overvoltage,” the Power Good pin will remain low, and the
device will latch off. To clear a latch fault, input voltage must
be recycled. Graphical representation of the OOV, OUV, and
Power Good pin functionality is shown in Figures 25
and 26.
SYNC
SYNC_in
³ 1.5 V *
OOV, OUV, and Power Good
Current
Sensor
1.21 V
F nom
F SYNC
GND
External Synchronization
The device can sync to frequencies that are 15% to 60%
higher than the nominal switching frequency. If an external
sync pulse is present at the SYNC pin prior to input voltage
application to the device, then no additional external
components are needed. If the external clock is not present
following power on reset of the device, the voltage on the
SYNC pin will determine whether the device is a master or
a slave. If the external clock source is meant to start after
device operation, its off state should be high or tristate. It is
also important to note that the slope of the internal ramp is
fixed and synchronizing to a faster clock which will truncate
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NCP3012
Soft Start Complete
V2 = Vref * 125%
Comparator 1
V4 = Vref * 110%
Comparator 2
V5 = Vref * 90%
FB
Power Good
Restart
LOGIC
Comparator 3
Latch off
V7= Vref * 75%
Comparator 4
Vref = 0.8 V
Figure 23. OOV, OUV, and Power Good Circuit Diagram
Trip Level Tolerance 2%
Hysteresis = 5 mV
Trip Level Tolerance 2%
Hysteresis = 5 mV
OOVP & Power Good = 0
Voov = Vref * 125%
Power Good = 0
Power Not good High
Vtrip_pg = Vref * 110%
Power Good = 1
Vref = 0.8 V
Trip Level Tolerance 2%
Hysteresis = 5 mV
Trip Level Tolerance 2%
Hysteresis = 5 mV
Power Good = 1
Vtrip_pg = Vref * 90%
Power Good = 0
Power Not Good Low
Vouv = Vref * 75%
OUVP & Power Good = 0
Figure 24. OOV, OUV, and Power Good Window Diagram
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NCP3012
1.0 V (vref * 125 %)
0.88 V (vref * 110 %)
0.8 V ( vref * 100 %)
0.72 V (vref * 90%)
0.60 V (vref * 75%)
FB Voltage
Latch off
Power Good
Power Good Pin
Reinitiate Softstart
Softstart Complete
Figure 25. Powerup Sequence and Overvoltage Latch
1.0 V (vref *125%)
0.88 V (vref *110%)
0.8 V (vref *100%)
0.72 V (vref *90%)
0.60 V (vref *75%)
FB Voltage
Latch off
Power Good
Power Good
Reinitiate Softstart
Softstart Complete
Figure 26. Powerup Sequence and Undervoltage Soft−Start
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NCP3012
CURRENT LIMIT AND CURRENT LIMIT SET
ILimit block consists of a voltage comparator circuit which
compares the differential voltage across the VCC Pin and the
VSW Pin with a resistor settable voltage reference. The sense
portion of the circuit is only active while the HS MOSFET
is turned ON.
Overview
The NCP3012 uses the voltage drop across the High Side
MOSFET during the on time to sense inductor current. The
VIN
VCC
VSense
Ilim Out
HSDR
Itrip Ref
VSW
Switch
Cap
CONTROL
Iset
13 uA
LSDR
6
Vset
DAC /
COUNTER
RSet
Itrip Ref−63 Steps, 6.51 mV/step
Figure 27. Iset / ILimit Block Diagram
Current Limit Set
prior to Soft−Start, the DAC counter increments the
reference on the ISET comparator until it crosses the VSET
voltage and holds the DAC reference output to that count
value. This voltage is translated to the ILimit comparator
during the ISense portion of the switching cycle through the
switch cap circuit. See Figure 27. Exceeding the maximum
sense voltage results in no current limit. Steps 0 to 10 result
in an effective current limit of 0 mV.
The ILimit comparator reference is set during the startup
sequence by forcing a typically 13 mA current through the
low side gate drive resistor. The gate drive output will rise
to a voltage level shown in the equation below:
V set + I set * R set
(eq. 4)
Where ISET is 13 mA and RSET is the gate to source resistor
on the low side MOSFET.
This resistor is normally installed to prevent MOSFET
leakage from causing unwanted turn on of the low side
MOSFET. In this case, the resistor is also used to set the
ILimit trip level reference through the ILimit DAC. The Iset
process takes approximately 350 ms to complete prior to
Soft−Start stepping. The scaled voltage level across the ISET
resistor is converted to a 6 bit digital value and stored as the
trip value. The binary ILimit value is scaled and converted to
the analog ILimit reference voltage through a DAC counter.
The DAC has 63 steps in 6.51 mV increments equating to a
maximum sense voltage of 403 mV. During the Iset period
Current Sense Cycle
Figure 28 shows how the current is sampled as it relates
to the switching cycle. Current level 1 in Figure 28
represents a condition that will not cause a fault. Current
level 2 represents a condition that will cause a fault. The
sense circuit is allowed to operate below the 3/4 point of a
given switching cycle. A given switching cycle’s 3/4 Ton
time is defined by the prior cycle’s Ton and is quantized in
10 ns steps. A fault occurs if the sensed MOSFET voltage
exceeds the DAC reference within the 3/4 time window of
the switching cycle.
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NCP3012
Trip:
Vsense > Itrip Ref at 3/4 Point
No Trip:
Vsense < Itrip Ref at 3/4 Point
Itrip Ref
Vsense
¾
¾
Current Level 1
Ton−1
Ton−2
Current Level 2
3/4 Point Determined by
Prior Cycle
1/4
1/2
1/4
1/2
3/4
3/4
Ton−1
Ton
Each switching cycle’s Ton is counted in 10 nS time steps. The 3/4 sample time
value is held and used for the following cycle’s limit sample time
Figure 28. ILimit Trip Point Description
Soft−Start Current limit
Boost Clamp Functionality
During soft−start the ISET value is doubled to allow for
inrush current to charge the output capacitance. The DAC
reference is set back to its normal value after soft−start has
completed.
The boost circuit requires an external capacitor connected
between the BST and VSW pins to store charge for supplying
the high and low−side gate driver voltage. This clamp circuit
limits the driver voltage to typically 7.5 V when VIN > 9 V,
otherwise this internal regulator is in dropout and typically
VIN − 1.25 V.
The boost circuit regulates the gate driver output voltage
and acts as a switching diode. A simplified diagram of the
boost circuit is shown in Figure 29. While the switch node
is grounded, the sampling circuit samples the voltage at the
boost pin, and regulates the boost capacitor voltage. The
sampling circuit stores the boost voltage while the VSW is
high and the linear regulator output transistor is reversed
biased.
VSW Ringing
The ILimit block can lose accuracy if there is excessive
VSW voltage ringing that extends beyond the 1/2 point of the
high−side transistor on−time. Proper snubber design and
keeping the ratio of ripple current and load current in the
10−30% range can help alleviate this as well.
Current Limit
A current limit trip results in completion of one switching
cycle and subsequently half of another cycle Ton to account
for negative inductor current that might have caused
negative potentials on the output. Subsequently the power
MOSFETs are both turned off and a 4 soft−start time period
wait passes before another soft−start cycle is attempted.
VIN
8.9V
Iave vs Trip Point
The average load trip current versus RSET value is shown
the equation below:
I AveTRIP +
I set
R set
R DS(on)
*
ƪ
1 V IN * V OUT
4
L
Switch
Sampling
Circuit
ƫ
V OUT
1
V IN
F SW
BST
VSW
LSDR
(eq. 5)
Where:
L = Inductance (H)
ISET = 13 mA
RSET = Gate to Source Resistance (W)
RDS(on) = On Resistance of the HS MOSFET (W)
VIN = Input Voltage (V)
VOUT = Output Voltage (V)
FSW = Switching Frequency (Hz)
Figure 29. Boost Circuit
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NCP3012
The boost ripple frequency is dependent on the output
capacitance selected. The ripple voltage will not damage the
device or $12 V gate rated MOSFETs.
Conditions where maximum boost ripple voltage could
damage the device or $12 V gate rated MOSFETs can be
seen in Region 3 (Orange). Placing a boost capacitor that is
no greater than 10X the input capacitance of the high side
MOSFET on the boost pin limits the maximum boost
voltage < 12 V. The typical drive waveforms for Regions 1,
2 and 3 (green, yellow, and orange) regions of Figure 30 are
shown in Figure 31.
Reduced sampling time occurs at high duty cycles where
the low side MOSFET is off for the majority of the switching
period. Reduced sampling time causes errors in the
regulated voltage on the boost pin. High duty cycle / input
voltage induced sampling errors can result in increased
boost ripple voltage or higher than desired DC boost voltage.
Figure 30 outlines all operating regions.
The recommended operating conditions are shown in
Region 1 (Green) where a 0.1 mF, 25 V ceramic capacitor
can be placed on the boost pin without causing damage to the
device or MOSFETS. Larger boost ripple voltage occurring
over several switching cycles is shown in Region 2 (Yellow).
Boost Voltage Levels
Normal Operation
Increased Boost Ripple
(Still in Specification)
Increased Boost Ripple
Capacitor Optimization
Required
28
Region 3
26
24
In p u t V o lt a g e
22
22V
20
18
Region 2
Maxi
mum
Max
Duty
Duty
Cycle
Cycle
Region 1
16
14
12
11.5V
10
8
71%
6
4
2
5
10
15
20
25
30
35
40
45
50
55
60
65
70
75
80
85
90
Duty Cycle
Figure 30. Safe Operating Area for Boost Voltage with a 0.1 mF Capacitor
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NCP3012
VIN
7.5V
VBOOST
7.5V
0V
Maximum
Normal
VIN
7.5V
VBOOST
7.5V
0V
Maximum
Normal
VIN
7.5V
VBOOST
7.5V
0V
Figure 31. Typical Waveforms for Region 1 (top), Region 2 (middle), and Region 3 (bottom)
To illustrate, a 0.1 mF boost capacitor operating at > 80% duty cycle and > 22.5 V input voltage will exceed the specifications
for the driver supply voltage. See Figure 32.
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NCP3012
Boost Voltage
18
Voltage Ripple
Maximum Allowable Voltage
Maximum Boost Voltage
16
14
Boost Voltage (V)
12
10
8
6
4
2
0
4.5
6.5
8.5
10.5
12.5
14.5
16.5
18.5
Input Voltage (V)
20.5
22.5
24.5
26.5
(Clarity on Boost Max and Ripple Def)
Figure 32. Boost Voltage at 80% Duty Cycle
Inductor Selection
D+
When selecting the inductor, it is important to know the
input and output requirements. Some example conditions
are listed below to assist in the process.
V OUT ) V LSD
V IN * V HSD ) V LSD
³ 27.5% +
Table 1. DESIGN PARAMETERS
Design Parameter
(VIN)
9 V to 18 V
Nominal Input Voltage
(VIN)
12 V
(VOUT)
3.3 V
Output Voltage
Input ripple voltage
(VINRIPPLE)
300 mV
(VOUTRIPPLE)
50 mV
Output current rating
(IOUT)
8A
Operating frequency
(Fsw)
75 kHz
D+
T ON
T
1
T
(* D Ǔ +
L+
+
T
12 V
DI
(eq. 9)
I OUT
V OUT
I OUT @ ra @ F SW
@ (1 * D) ³ 22 mH
3.3 V
8 A @ 25% @ 75 kHz
(eq. 10)
@ (1 * 27.5%)
The relationship between ra and L for this design example
is shown in Figure 33.
(eq. 6)
T OFF
(eq. 8)
The designer should employ a rule of thumb where the
percentage of ripple current in the inductor lies between
10% and 40%. When using ceramic output capacitors the
ripple current can be greater thus a user might select a higher
ripple current, but when using electrolytic capacitors a lower
ripple current will result in lower output ripple. Now,
acceptable values of inductance for a design can be
calculated using Equation 10.
A buck converter produces input voltage (VIN) pulses that
are LC filtered to produce a lower dc output voltage (VOUT).
The output voltage can be changed by modifying the on time
relative to the switching period (T) or switching frequency.
The ratio of high side switch on time to the switching period
is called duty cycle (D). Duty cycle can also be calculated
using VOUT, VIN, the low side switch voltage drop VLSD,
and the High side switch voltage drop VHSD.
F+
V IN
3.3 V
ra +
Output ripple voltage
V OUT
The ratio of ripple current to maximum output current
simplifies the equations used for inductor selection. The
formula for this is given in Equation 9.
Example Value
Input Voltage
[D+
(eq. 7)
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NCP3012
100
95
90 18 Vin
85
80
75
70
65
60
55 12 Vin
50
45
40
35
30
25
20 9 V
in
15
10
5
10%
15%
I PP +
Vout = 3.3 V
35%
40%
LP CU + I RMS 2 @ DCR
To keep within the bounds of the parts maximum rating,
calculate the RMS current and peak current.
+8A@
ǒ
I PK + I OUT @ 1 )
Ǹ1 ) ra12 ³ 8.02 A
2
Ǹ1 ) (0.25)
12
LP tot + LP CU_DC ) LP CU_AC ) LP Core (eq. 16)
(eq. 11)
2
Input Capacitor Selection
ǒ
Ǔ
ra
³ 9.0 A + 8 A @ 1 )
2
(0.25)
2
The input capacitor has to sustain the ripple current
produced during the on time of the upper MOSFET, so it
must have a low ESR to minimize the losses. The RMS value
of this ripple is:
Ǔ
(eq. 12)
Iin RMS + I OUT @ ǸD @ (1 * D)
An inductor for this example would be around 3.3 mH and
should support an rms current of 8.02 A and a peak current
of 9.0 A.
The final selection of an output inductor has both
mechanical and electrical considerations. From a
mechanical perspective, smaller inductor values generally
correspond to smaller physical size. Since the inductor is
often one of the largest components in the regulation system,
a minimum inductor value is particularly important in
space−constrained applications. From an electrical
perspective, the maximum current slew rate through the
output inductor for a buck regulator is given by Equation 13.
SlewRate LOUT +
V IN * V OUT
L OUT
³ 0.4
(eq. 15)
The core losses and ac copper losses will depend on the
geometry of the selected core, core material, and wire used.
Most vendors will provide the appropriate information to
make accurate calculations of the power dissipation then the
total inductor losses can be capture buy the equation below:
Figure 33. Ripple Current Ratio vs. Inductance
I RMS + I OUT @
(eq. 14)
L OUT @ F SW
Ipp is the peak to peak current of the inductor. From this
equation it is clear that the ripple current increases as LOUT
decreases, emphasizing the trade−off between dynamic
response and ripple current.
The power dissipation of an inductor consists of both
copper and core losses. The copper losses can be further
categorized into dc losses and ac losses. A good first order
approximation of the inductor losses can be made using the
DC resistance as they usually contribute to 90% of the losses
of the inductor shown below:
L, INDUCTANCE (mH)
20%
25%
30%
Ripple Current Ratio (%)
V OUT(1 * D)
(eq. 17)
D is the duty cycle, IinRMS is the input RMS current, and
IOUT is the load current.
The equation reaches its maximum value with D = 0.5.
Loss in the input capacitors can be calculated with the
following equation:
P CIN + ESR CIN @ ǒI IN*RMSǓ
2
(eq. 18)
PCIN is the power loss in the input capacitors and ESRCIN
is the effective series resistance of the input capacitance.
Due to large dI/dt through the input capacitors, electrolytic
or ceramics should be used. If a tantalum must be used, it
must by surge protected. Otherwise, capacitor failure could
occur.
12 V * 3.3 V
A
+
ms
22 mH
(eq. 13)
Input Start−up Current
This equation implies that larger inductor values limit the
regulator’s ability to slew current through the output
inductor in response to output load transients. Consequently,
output capacitors must supply the load current until the
inductor current reaches the output load current level. This
results in larger values of output capacitance to maintain
tight output voltage regulation. In contrast, smaller values of
inductance increase the regulator’s maximum achievable
slew rate and decrease the necessary capacitance, at the
expense of higher ripple current. The peak−to−peak ripple
current for the NCP3012 is given by the following equation:
To calculate the input startup current, the following
equation can be used.
I INRUSH +
C OUT @ V OUT
t SS
(eq. 19)
Iinrush is the input current during startup, COUT is the total
output capacitance, VOUT is the desired output voltage, and
tSS is the soft start interval. If the inrush current is higher than
the steady state input current during max load, then the input
fuse should be rated accordingly, if one is used.
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NCP3012
Output Capacitor Selection
In a typical converter design, the ESR of the output capacitor
bank dominates the transient response. It should be noted
that DVOUT−DISCHARGE and DVOUT−ESR are out of
phase with each other, and the larger of these two voltages
will determine the maximum deviation of the output voltage
(neglecting the effect of the ESL).
Conversely during a load release, the output voltage can
increase as the energy stored in the inductor dumps into the
output capacitor. The ESR contribution from Equation 21
still applies in addition to the output capacitor charge which
is approximated by the following equation:
The important factors to consider when selecting an
output capacitor is dc voltage rating, ripple current rating,
output ripple voltage requirements, and transient response
requirements.
The output capacitor must be rated to handle the ripple
current at full load with proper derating. The RMS ratings
given in datasheets are generally for lower switching
frequency than used in switch mode power supplies but a
multiplier is usually given for higher frequency operation.
The RMS current for the output capacitor can be calculated
below:
ra
Co RMS + I O @
Ǹ12
2
DV OUT−CHG +
(eq. 20)
The maximum allowable output voltage ripple is a
combination of the ripple current selected, the output
capacitance selected, the equivalent series inductance (ESL)
and ESR.
The main component of the ripple voltage is usually due
to the ESR of the output capacitor and the capacitance
selected.
ǒ
V ESR_C + I O @ ra @ ESR Co )
Ǔ
1
8 @ F SW @ Co
ESL @ I PP @ F SW
V ESLOFF +
D
ESL @ I PP @ F SW
(1 * D )
Power dissipation, package size, and the thermal
environment drive MOSFET selection. To adequately select
the correct MOSFETs, the design must first predict its power
dissipation. Once the dissipation is known, the thermal
impedance can be calculated to prevent the specified
maximum junction temperatures from being exceeded at the
highest ambient temperature.
Power dissipation has two primary contributors:
conduction losses and switching losses. The control or
high−side MOSFET will display both switching and
conduction losses. The synchronous or low−side MOSFET
will exhibit only conduction losses because it switches into
nearly zero voltage. However, the body diode in the
synchronous MOSFET will suffer diode losses during the
non−overlap time of the gate drivers.
Starting with the high−side or control MOSFET, the
power dissipation can be approximated from:
(eq. 21)
(eq. 22)
P D_CONTROL + P COND ) P SW_TOT
(eq. 23)
2
P COND + ǒI RMS_CONTROLǓ @ R DS(on)_CONTROL (eq. 28)
Using the ra term from Equation 9, IRMS becomes:
I RMS_CONTROL + I OUT @
C OUT @ ǒV IN * V OUTǓ
ǒ ǒra12 ǓǓ
D@ 1)
2
P SW_TOT + P SW ) P DS ) P RR
(eq. 24)
(eq. 29)
(eq. 30)
The first term for total switching losses from Equation 30
includes the losses associated with turning the control
MOSFET on and off and the corresponding overlap in drain
voltage and current.
P SW + P TON ) P TOFF
2
DV OUT−DISCHG +
Ǹ
The second term from Equation 27 is the total switching
loss and can be approximated from the following equations.
A minimum capacitor value is required to sustain the
current during the load transient without discharging it. The
voltage drop due to output capacitor discharge is
approximated by the following equation:
ǒI TRANǓ @ LOUT
(eq. 27)
The first term is the conduction loss of the high−side
MOSFET while it is on.
The output capacitor is a basic component for the fast
response of the power supply. In fact, during load transient,
for the first few microseconds it supplies the current to the
load. The controller immediately recognizes the load
transient and sets the duty cycle to maximum, but the current
slope is limited by the inductor value.
During a load step transient the output voltage initially
drops due to the current variation inside the capacitor and the
ESR (neglecting the effect of the effective series inductance
(ESL)).
DV OUT−ESR + DI TRAN @ ESR Co
(eq. 26)
C OUT @ V OUT
Power MOSFET Selection
The ESL of capacitors depends on the technology chosen
but tends to range from 1 nH to 20 nH where ceramic
capacitors have the lowest inductance and electrolytic
capacitors then to have the highest. The calculated
contributing voltage ripple from ESL is shown for the switch
on and switch off below:
V ESLON +
ǒI TRANǓ @ LOUT
+ 1 @ ǒI OUT @ V IN @ f SWǓ @ ǒt ON ) t OFFǓ
2
(eq. 25)
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22
(eq. 31)
NCP3012
where:
t ON +
Q GD
I G1
+
Q GD
ǒV BST * V THǓńǒR HSPU ) R GǓ
IG1: output current from the high−side gate drive (HSDR)
IG2: output current from the low−side gate drive (LSDR)
ƒSW: switching frequency of the converter.
VBST: gate drive voltage for the high−side drive, typically
7.5 V.
QGD: gate charge plateau region, commonly specified in the
MOSFET datasheet
VTH: gate−to−source voltage at the gate charge plateau
region
QOSS: MOSFET output gate charge specified in the data
sheet
QRR: reverse recovery charge of the low−side or
synchronous MOSFET, specified in the datasheet
RDS(on)_CONTROL: on resistance of the high−side, or
control, MOSFET
RDS(on)_SYNC: on resistance of the low−side, or
synchronous, MOSFET
NOLLH: dead time between the LSDR turning off and the
HSDR turning on, typically 85 ns
NOLHL: dead time between the HSDR turning off and the
LSDR turning on, typically 75 ns
(eq. 32)
and:
t OFF +
Q GD
I G2
+
Q GD
ǒV BST * V THǓńǒR HSPD ) R GǓ
(eq. 33)
Next, the MOSFET output capacitance losses are caused
by both the control and synchronous MOSFET but are
dissipated only in the control MOSFET.
P DS + 1 @ Q OSS @ V IN @ f SW
2
(eq. 34)
Finally the loss due to the reverse recovery time of the
body diode in the synchronous MOSFET is shown as
follows:
P RR + Q RR @ V IN @ f SW
(eq. 35)
The low−side or synchronous MOSFET turns on into zero
volts so switching losses are negligible. Its power
dissipation only consists of conduction loss due to RDS(on)
and body diode loss during the non−overlap periods.
P D_SYNC + P COND ) P BODY
Once the MOSFET power dissipations are determined,
the designer can calculate the required thermal impedance
for each device to maintain a specified junction temperature
at the worst case ambient temperature. The formula for
calculating the junction temperature with the package in free
air is:
(eq. 36)
Conduction loss in the low−side or synchronous
MOSFET is described as follows:
2
P COND + ǒI RMS_SYNCǓ @ R DS(on)_SYNC (eq. 37)
where:
I RMS_SYNC + I OUT @
T J + T A ) P D @ R qJA
Ǹ
ǒ ǒ ǓǓ
ra 2
( 1 * D) @ 1 )
12
TJ: Junction Temperature
TA: Ambient Temperature
PD: Power Dissipation of the MOSFET under analysis
RqJA: Thermal Resistance Junction−to−Ambient of the
MOSFET’s package
(eq. 38)
The body diode losses can be approximated as:
P BODY + V FD @ I OUT @ f SW @ ǒNOL LH ) NOL HLǓ (eq. 39)
As with any power design, proper laboratory testing
should be performed to insure the design will dissipate the
required power under worst case operating conditions.
Variables considered during testing should include
maximum ambient temperature, minimum airflow,
maximum input voltage, maximum loading, and component
variations (i.e. worst case MOSFET RDS(on)).
Vth
Figure 34. MOSFET Switching Characteristics
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NCP3012
NOLHL
NOLLH
High−Side
Logic Signal
Low−Side
Logic Signal
td(on)
tf
RDSmax
High−Side
MOSFET
RDS(on)min
tr
td(off)
tr
tf
RDSmax
Low−Side
MOSFET
RDS(on)min
td(on)
td(off)
Figure 35. MOSFETs Timing Diagram
response. The goal of the compensation circuit is to provide
a loop gain function with the highest crossing frequency and
adequate phase margin (minimally 45°). The transfer
function of the power stage (the output LC filter) is a double
pole system. The resonance frequency of this filter is
expressed as follows:
Another consideration during MOSFET selection is their
delay times. Turn−on and turn−off times must be short
enough to prevent cross conduction. If not, there will be
conduction from the input through both MOSFETs to
ground. Therefore, the following conditions must be met.
t d(ON)_CONTROL ) NOL LH u t d(OFF)_SYNC ) t f_SYNC
f P0 +
(eq. 40)
and
t (ON)_SYNC ) NOL HL u t d(OFF)_CONTROL ) t f _CONTROL
1
2 @ p @ ǸL @ C OUT
(eq. 41)
Parasitic Equivalent Series Resistance (ESR) of the
output filter capacitor introduces a high frequency zero to
the filter network. Its value can be calculated by using the
following equation:
The MOSFET parameters, td(ON), tr, td(OFF) and tf are can
be found in their appropriate datasheets for specific
conditions. NOLLH and NOLHL are the dead times which
were described earlier and are 85 ns and 75 ns, respectively.
f Z0 +
Feedback and Compensation
The NCP3012 is a voltage mode buck convertor with a
transconductance error amplifier compensated by an
external compensation network. Compensation is needed to
achieve accurate output voltage regulation and fast transient
1
2 @ p @ C OUT @ ESR
(eq. 42)
The main loop zero crossover frequency f0 can be chosen
to be 1/10 − 1/5 of the switching frequency. Table 2 shows
the three methods of compensation.
Table 2. COMPENSATION TYPES
Zero Crossover Frequency Condition
Compensation Type
Typical Output Capacitor Type
fP0 < fZ0 < f0 < fS/2
Type II
Electrolytic, Tantalum
fP0 < f0 < fZ0 < fS/2
Type III Method I
Tantalum, Ceramic
fP0 < f0 < fS/2 < fZ0
Type III Method II
Ceramic
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24
NCP3012
Compensation Type II
This compensation is suitable for electrolytic capacitors.
Components of the Type II compensation (Figure 36)
network can be specified by the following equations:
f Z1 + 0.75 @ f P0
(eq. 47)
f Z2 + f P0
(eq. 48)
f P2 + f Z0
(eq. 49)
fS
f P3 +
(eq. 50)
2
Method II is better suited for ceramic capacitors that
typically have the lowest ESR available:
Figure 36. Type II Compensation
R C1 +
2 @ p @ f 0 @ L @ V RAMP @ V OUT
ESR @ V IN @ V ref @ gm
(eq. 44)
C C2 +
1
p @ R C1 @ f S
(eq. 45)
V ref
@ R2
(eq. 51)
f P2 + f 0 @
sin q max
Ǹ11 *) sin
q max
(eq. 52)
f Z1 + 0.5 @ f Z2
(eq. 53)
f P3 + 0.5 @ f S
(eq. 54)
R C1 u u
1
0.75 @ 2 @ p @ f P0 @ R C1
V OUT * V ref
sinq max
Ǹ11 )* sin
q max
The remaining calculations are the same for both methods.
(eq. 43)
C C1 +
R1 +
f Z2 + f 0 @
1
2 @ p @ f Z1 @ R C1
(eq. 56)
C C2 +
1
2 @ p @ f P3 @ R C1
(eq. 57)
C FB1 +
R FB1 +
Compensation Type III
R1 +
Tantalum and ceramics capacitors have lower ESR than
electrolytic, so the zero of the output LC filter goes to a
higher frequency above the zero crossover frequency. This
requires a Type III compensation network as shown in
Figure 37.
There are two methods to select the zeros and poles of this
compensation network. Method I is ideal for tantalum
output capacitors, which have a higher ESR than ceramic:
R2 +
(eq. 55)
C C1 +
(eq. 46)
VRAMP is the peak−to−peak voltage of the oscillator ramp
and gm is the transconductance error amplifier gain.
Capacitor CC2 is optional.
2
gm
2 @ p @ f 0 @ L @ V RAMP @ C OUT
V IN @ R C1
1
2p @ C FB1 @ f P2
(eq. 59)
1
* R FB1
2 @ p @ C FB1 @ f Z2
V
ref
V OUT * V ref
(eq. 58)
(eq. 60)
@ R1
(eq. 61)
If the equation in Equation 62 is not true, then a higher value
of RC1 must be selected.
R1 @ R2 @ R FB1
R1 @ R FB1 ) R2 @ R FB1 ) R1 @ R2
Figure 37. Type III Compensation
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25
u
1
(eq. 62)
gm
NCP3012
PACKAGE DIMENSIONS
TSSOP−14
CASE 948G−01
ISSUE B
14X K REF
0.10 (0.004)
0.15 (0.006) T U
M
T U
V
S
S
N
2X
14
L/2
0.25 (0.010)
8
M
B
−U−
L
PIN 1
IDENT.
N
F
7
1
0.15 (0.006) T U
NOTES:
1. DIMENSIONING AND TOLERANCING PER
ANSI Y14.5M, 1982.
2. CONTROLLING DIMENSION: MILLIMETER.
3. DIMENSION A DOES NOT INCLUDE MOLD
FLASH, PROTRUSIONS OR GATE BURRS.
MOLD FLASH OR GATE BURRS SHALL NOT
EXCEED 0.15 (0.006) PER SIDE.
4. DIMENSION B DOES NOT INCLUDE
INTERLEAD FLASH OR PROTRUSION.
INTERLEAD FLASH OR PROTRUSION SHALL
NOT EXCEED 0.25 (0.010) PER SIDE.
5. DIMENSION K DOES NOT INCLUDE DAMBAR
PROTRUSION. ALLOWABLE DAMBAR
PROTRUSION SHALL BE 0.08 (0.003) TOTAL
IN EXCESS OF THE K DIMENSION AT
MAXIMUM MATERIAL CONDITION.
6. TERMINAL NUMBERS ARE SHOWN FOR
REFERENCE ONLY.
7. DIMENSION A AND B ARE TO BE
DETERMINED AT DATUM PLANE −W−.
S
S
DETAIL E
K
A
−V−
ÉÉÉ
ÇÇÇ
ÇÇÇ
ÉÉÉ
K1
J J1
SECTION N−N
−W−
C
0.10 (0.004)
−T− SEATING
PLANE
D
G
H
DETAIL E
DIM
A
B
C
D
F
G
H
J
J1
K
K1
L
M
MILLIMETERS
INCHES
MIN
MAX
MIN MAX
4.90
5.10 0.193 0.200
4.30
4.50 0.169 0.177
−−−
1.20
−−− 0.047
0.05
0.15 0.002 0.006
0.50
0.75 0.020 0.030
0.65 BSC
0.026 BSC
0.50
0.60 0.020 0.024
0.09
0.20 0.004 0.008
0.09
0.16 0.004 0.006
0.19
0.30 0.007 0.012
0.19
0.25 0.007 0.010
6.40 BSC
0.252 BSC
0_
8_
0_
8_
SOLDERING FOOTPRINT
7.06
1
0.65
PITCH
14X
0.36
14X
1.26
DIMENSIONS: MILLIMETERS
ON Semiconductor and
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NCP3012/D