MPQ8623
16V, 6A, High Efficiency, Synchronous,
Step-Down Converter with
Adjustable Current Limit
DESCRIPTION
The MPQ8623 is a fully integrated, highfrequency, synchronous, buck converter. The
MPQ8623 offers a very compact solution that
achieves up to 6A of output current with excellent
load and line regulation over a wide input supply
range. The MPQ8623 operates at high efficiency
over a wide output current load range.
The
MPQ8623
adopts
an
internally
compensated constant-on-time (COT) control
that provides fast transient response and eases
loop stabilization.
The operating frequency can be set to 600kHz,
1100kHz, or 2000kHz easily with MODE
configuration, allowing the MPQ8623 frequency
to remain constant regardless of the input and
output voltages.
The output voltage start-up ramp is controlled by
an internal 1.5ms timer, which can be increased
by adding a capacitor on TRK/REF. An opendrain power good (PGOOD) signal indicates if
the output is within its nominal voltage range.
PGOOD is clamped to around 0.7V with an
external pull-up voltage when the input supply
fails to power the MPQ8623.
Full protection features include over-current
protection (OCP), over-voltage protection
(OVP), under-voltage protection (UVP), and
over-temperature protection (OTP).
The MPQ8623 requires a minimal number of
readily available, standard, external components
and is available in a QFN-14 (2mmx3mm)
package.
FEATURES
Wide Input Voltage Range
o 2.85V to 16V with External 3.3V VCC
Bias
o 4V to 16V with Internal VCC Bias or
External 3.3V VCC Bias
6A Output Current
Programmable Accurate Current Limit Level
Low RDS(ON) Integrated Power MOSFETs
Proprietary Switching Loss Reduction
Technique
Adaptive Constant-On-Time (COT) for
Ultrafast Transient Response
Stable with Zero ESR Output Capacitor
0.5% Reference Voltage Over 0°C to
+70°C Junction Temperature Range
1% Reference Voltage Over -40°C to
+125°C Junction Temperature Range
Selectable Forced CCM or Pulse-Skip
Operation
Excellent Load Regulation
Output Voltage Tracking
Output Voltage Discharge
PGOOD Active Clamped at Low Level
during Power Failure
Programmable Soft-Start Time from 1.5ms
and Up
Pre-Bias Start-Up
Selectable Switching Frequency from
600kHz, 1100kHz, and 2000kHz
Latch-Off for OCP, OVP, UVP, OTP, and
UVLO
Output Adjustable from 0.9V to 0.9 x VIN Up
to 6V Max
Available in a QFN-14 (2mmx3mm)
Package
APPLICATIONS
Telecom and Networking Systems
Servers, Cloud-Computing, Storage
Base Stations
General Purpose Point-of-Load (PoL)
12V Distribution Power Systems
High-end TV
Game Consoles and Graphic Cards
All MPS parts are lead-free, halogen-free, and adhere to the RoHS directive.
For MPS green status, please visit the MPS website under Quality
Assurance. “MPS” and “The Future of Analog IC Technology” are registered
trademarks of Monolithic Power Systems, Inc.
MPQ8623 Rev. 1.01
www.MonolithicPower.com
10/2/2018
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�MPQ8623 – 16V, 6A, HIGH EFFICIENCY SYNC STEP-DOWN CONVERTER W/ ADJUSTABLE CURRENT LIMIT
TYPICAL APPLICATION
C3
VIN
VIN
BST
L1
Vout
SW
CIN
MPQ8623
EN
EN
PG
PGOOD
C1
R1
COUT
FB
VCC
CVCC
R2
MODE
AGND
TRK/REF
CS
RCS
PGND
CREF
MPQ8623 Rev. 1.01
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�MPQ8623 – 16V, 6A, HIGH EFFICIENCY SYNC STEP-DOWN CONVERTER W/ ADJUSTABLE CURRENT LIMIT
ORDERING INFORMATION
Part Number*
MPQ8623GD
Package
QFN-14 (2mmx3mm)
Top Marking
See Below
* For Tape & Reel, add suffix –Z (e.g. MPQ8623GD–Z)
TOP MARKING
ARM: Product code of MPQ8623GD
Y: Year code
WW: Week code
LLL: Lot number
PACKAGE REFERENCE
TOP VIEW
PGND VCC
13
14
PGND 1
12 MODE
SW 2
11 SW
VIN 3
10 BST
CS 4
9 PGOOD
EN 5
8 TRK/REF
6
7
FB AGND
QFN-14 (2mmx3mm)
MPQ8623 Rev. 1.01
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�MPQ8623 – 16V, 6A, HIGH EFFICIENCY SYNC STEP-DOWN CONVERTER W/ ADJUSTABLE CURRENT LIMIT
ABSOLUTE MAXIMUM RATINGS
(1)
Supply voltage (VIN) ....................................18V
VSW(DC)................................. -0.3V to VIN + 0.3V
VSW (25ns) (2) ..................................... -3V to 25V
VSW (25ns)......................................... -5V to 25V
VBST .....................................................VSW + 4V
VCC, EN ................................................... 4.5V
All other pins ................................. -0.3V to 4.3V
Junction temperature ............................... 170°C
Lead temperature .................................... 260°C
Storage temperature ................ -65°C to +170°C
Recommended Operating Conditions (3)
Supply voltage (VIN) .......................... 4V to 16V
VIN(DC) - VSW(DC) (4) ................. -0.3V to VIN + 0.3V
VSW(DC) (5) ............................. -0.3V to VIN + 0.3V
Output voltage (VOUT) ........................ 0.9V to 6V
External VCC bias (VCC_EXT) ......... 3.12V to 3.6V
Maximum output current (IOUT_MAX) .................6A
Maximum output current limit (IOC_MAX) ...........8A
Maximum peak inductor current (IL_PEAK) ......10A
EN voltage (VEN) .........................................3.6V
Operating junction temp. (TJ). .. -40°C to +125°C
Thermal Resistance (6)
θJB θJC_TOP
QNF-14 (2mmx3mm) ...........6.8..... 17.4 ... °C/W
NOTES:
1) Exceeding these ratings may damage the device.
2) Measured by using a differential oscilloscope probe.
3) The device is not guaranteed to function outside of its operating
conditions.
4) The voltage rating can be in the range of -5V to 24V for a period
of 25ns or less with a maximum repetition rate of 2MHz when
the input voltage is 16V.
5) The voltage rating can be in the range of -3V to 24V for a period
of 25ns or less with a maximum repetition rate of 2MHz when
the input voltage is 16V.
6) θJB is the thermal resistance from the junction to the board
around the PGND soldering point.
θJC_TOP is the thermal resistance from the junction to the top of
the package.
MPQ8623 Rev. 1.01
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�MPQ8623 – 16V, 6A, HIGH EFFICIENCY SYNC STEP-DOWN CONVERTER W/ ADJUSTABLE CURRENT LIMIT
ELECTRICAL CHARACTERISTICS
VIN = 12V, TJ = -40°C to 125°C, unless otherwise noted.
Parameters
VIN Supply Current
Supply current (shutdown)
Supply current (quiescent)
MOSFET
Switch leakage
HS on-state resistance
LS on-state resistance
Current Limit
Current limit threshold
ICS to IOUT ratio
Low-side negative current limit
Negative current limit time-out (7)
Timer
Switching frequency (8)
Symbol
IIN
IIN
SW LKG_HS
SW LKG_LS
RDS_ON_HS
RDS_ON_LS
VLIM
ICS/IOUT
Condition
Min
Typ
Max
Units
VEN = 0V
VEN = 2V, VFB = 1V
0
650
10
850
μA
μA
VEN = 0V, VSW = 0V
VEN = 0V, VSW = 12V
VEN = 2V @ 25°C
VEN = 2V @ 25°C
0
0
22.6
8.1
10
30
μA
IOUT ≥ 2A
1.15
36
1.2
40
-8
80
1.25
44
V
μA/A
A
ns
VOUT=1V
VOUT=1V
VOUT=3.3V
530
935
1870
660
1100
2200
790
1265
2530
50
180
kHz
kHz
kHz
ns
ns
113%
77%
116%
80%
119%
83%
VREF
VREF
891
895
900
900
15
6
1.5
909
905
mV
mV
μA
μA
ms
-3
0
50
3
100
mV
nA
1.17
1.22
200
0
80
1.27
V
mV
μA
Ω
2.25
2.55
2.85
V
1.7
2
2.3
V
ILIM_NEG_10
tNCL_Timer
fSW
mΩ
mΩ
Minimum on time (7)
TON_MIN
Minimum off time (7)
TOFF_MIN
VFB = 1000mV
Over-Voltage (OVP) and Under-Voltage Protection (UVP)
OVP threshold
VOVP
UVP threshold
VUVP
Feedback Voltage and Soft Start (SS)
TJ = -40°C to +125°C
Feedback voltage
VREF
TJ = 0°C to +70°C
TRK/REF sourcing current
ITRACK_Source VTRK/REF = 0V
TRK/REF sinking current
ITRACK_Sink
VTRK/REF = 1V
Soft-start time
tSS
CTRACK = 1nF
Error Amplifier (EA)
Error amplifier offset
VOS
Feedback current
IFB
VFB = REF
Enable (EN)
Enable input rising threshold
VIHEN
Enable hysteresis
VEN-HYS
Enable input current
IEN
VEN = 2V
Soft shutdown discharge FET
RON_DISCH
VIN UVLO
VIN under-voltage lockout
VINVth-Rise
threshold rising
VCC = 3.3V
VIN under-voltage lockout
VINVth-Fall
threshold falling
1
MPQ8623 Rev. 1.01
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�MPQ8623 – 16V, 6A, HIGH EFFICIENCY SYNC STEP-DOWN CONVERTER W/ ADJUSTABLE CURRENT LIMIT
ELECTRICAL CHARACTERISTICS (continued)
VIN = 12V, TJ = -40°C to +125°C, unless otherwise noted.
Parameters
VCC Regulator
Symbol
Condition
Min
Typ
Max
Units
VCC under-voltage lockout
threshold rising
VCCVth_Rise
2.65
2.8
2.95
V
VCC under-voltage lockout
threshold falling
VCCVth_Fall
2.35
2.5
2.65
V
VCC
2.88
3.00
0.5
3.12
V
%
89.5%
113%
77%
92.5%
116%
80%
95.5%
119%
83%
VREF
VREF
VREF
0.7
1
1.3
ms
0.5
V
3
µA
VCC output voltage
VCC load regulation
Power Good (PGOOD)
Power good high threshold
Power good low threshold
Power good low-to-high delay
Power good sink current
capability
Power good leakage current
Power good low-level output
voltage
ICC = 25mA
PGVth_Hi_Rise
PGVth_Lo_Rise
PGVth_Lo_Fall
PGTd
VPG
IPG_LEAK
VOL_100
VOL_10
FB from low to high
FB from low to high
FB from high to low
TJ = 25°C
IPG = 10mA
VPG = 3V
VIN = 0V, pull PGOOD up to
3.3V through a 100kΩ
resistor
650
850
mV
VIN = 0V, pull PGOOD up to
3.3V through a 10kΩ resistor
800
1000
Thermal Protection (OTP)
OTP shutdown (7)
OTP shutdown hysteresis (7)
TSD
TSD_Hys
150
160
20
°C
°C
NOTES:
7) Specified by design and characterization. Not production tested.
8) Specified by design.
MPQ8623 Rev. 1.01
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10/2/2018
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�MPQ8623 – 16V, 6A, HIGH EFFICIENCY SYNC STEP-DOWN CONVERTER W/ ADJUSTABLE CURRENT LIMIT
TYPICAL PERFORMANCE CHARACTERISTICS
VIN = 12V, VOUT = 1.8V, L = 1µH, TA = +25°C, unless otherwise noted.
MPQ8623 Rev. 1.01
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�MPQ8623 – 16V, 6A, HIGH EFFICIENCY SYNC STEP-DOWN CONVERTER W/ ADJUSTABLE CURRENT LIMIT
TYPICAL PERFORMANCE CHARACTERISTICS (continued)
VIN = 12V, VOUT = 1.8V, L = 1µH, TA = +25°C, unless otherwise noted.
MPQ8623 Rev. 1.01
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�MPQ8623 – 16V, 6A, HIGH EFFICIENCY SYNC STEP-DOWN CONVERTER W/ ADJUSTABLE CURRENT LIMIT
TYPICAL PERFORMANCE CHARACTERISTICS (continued)
VIN = 12V, VOUT = 1.8V, L = 1µH, TA = +25°C, unless otherwise noted.
MPQ8623 Rev. 1.01
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10/2/2018
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�MPQ8623 – 16V, 6A, HIGH EFFICIENCY SYNC STEP-DOWN CONVERTER W/ ADJUSTABLE CURRENT LIMIT
TYPICAL PERFORMANCE CHARACTERISTICS (continued)
VIN = 12V, VOUT = 1.8V, L = 1µH, TA = +25°C, unless otherwise noted.
MPQ8623 Rev. 1.01
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�MPQ8623 – 16V, 6A, HIGH EFFICIENCY SYNC STEP-DOWN CONVERTER W/ ADJUSTABLE CURRENT LIMIT
PIN FUNCTIONS
PIN #
Name
1, 14
PGND
2, 11
SW
3
VIN
4
CS
5
EN
6
FB
7
AGND
8
TRK/REF
9
PGOOD
10
BST
12
MODE
13
VCC
Description
System ground. PGND is the reference ground of the regulated output voltage.
PGND requires careful consideration during PCB layout. Connect using wide PCB
traces.
Switch output. Connect SW to the inductor and bootstrap capacitor. SW is driven
up to VIN by the high-side switch during the on-time of the PWM duty cycle. The
inductor current drives SW low during the off-time. Connect using wide PCB traces.
Input voltage. VIN supplies power for the internal MOSFET and regulator. Input
capacitors are needed to decouple the input rail. Connect using wide PCB traces.
Current limit. Connect a resistor to ground to set the current limit trip point. See
Table 2 for additional details.
Enable. EN is an input signal that turns the regulator on or off. Drive EN high to turn
on the regulator; drive EN low to turn off the regulator. Connect EN to VIN through a
pull-up resistor or a resistive voltage divider for automatic start-up. Do not float EN.
Feedback. An external resistor divider from the output to AGND tapped to FB sets
the output voltage. It is recommended to place the resistor divider as close to FB as
possible. Vias should be avoided on the FB traces.
Analog ground. Select AGND as the control circuit reference point.
External tracking voltage input. The output voltage tracks this input signal.
Decouple TRK/REF with a ceramic capacitor as close to it as possible. Ceramic
capacitors with X7R or X5R grade dielectrics are recommended for their stable
temperature characteristics. The capacitance of this capacitor determines the softstart time. See Equation 2 and 3 for additional details.
Power good output. PGOOD is an open-drain signal. A pull-up resistor connected
to a DC voltage is required to indicate a logic high signal if the output voltage is within
regulation. There is a delay of about 1ms from the time FB ≥ 92.5% and PGOOD
pulling high.
Bootstrap. Connect a capacitor between SW and BS to form a floating supply across
the high-side switch driver.
Operation mode selection. Program MODE to select CCM, pulse-skip mode, and
the operating switching frequency. See Table 1 for additional details.
Internal 3V LDO output. The driver and control circuits are powered from the VCC
voltage. Decouple VCC with a minimum 1µF ceramic capacitor as close to it as
possible. Ceramic capacitors with X7R or X5R grade dielectrics are recommended
for their stable temperature characteristics.
MPQ8623 Rev. 1.01
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�MPQ8623 – 16V, 6A, HIGH EFFICIENCY SYNC STEP-DOWN CONVERTER W/ ADJUSTABLE CURRENT LIMIT
BLOCK DIAGRAM
IN
MODE
VCC
MODE
SELECT
3V LDO
BST
REG
EN
REFERENCE
SYSTEM
MONITOR
HS
Driver
xS
OV_TH UV_TH
xR
FB
Q
HSG
LSG
TRK/REF
Error
Amplifier
BST
OFF
TIMER
Logic
Control
SW
ON
TIMER
PWM
Comparator
HSG
LSG
LS
Driver
RAMP
ZCD
Valley
Current
xLIM Limit &
ZCD
PGOOD
Comparator
OV_TH
OV Detect
Comparator
PGOOD
PGND
CS
UV_TH
FAULT
UV Detect
Comparator
AGND
Figure 1: Functional Block Diagram
MPQ8623 Rev. 1.01
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�MPQ8623 – 16V, 6A, HIGH EFFICIENCY SYNC STEP-DOWN CONVERTER W/ ADJUSTABLE CURRENT LIMIT
OPERATION
CONSTANT-ON-TIME (COT) Control
The MPQ8623 employs constant-on-time (COT)
control to achieve fast load transient response.
Figure 2 shows the details of the control stage of
the MPQ8623.
The operational amplifier (AMP) corrects any
error voltage between FB and VREF. The
MPQ8623 can use AMP to provide excellent
load regulation over the entire load range
whether it is operating in forced continuous
conduction mode (CCM) or pulse-skip mode.
The dedicated VSNS pin helps provide the
feature of the differential output voltage remote
sense. The pair of the remote sense trace should
be kept at a low impedance to achieve the best
performance.
The
MPQ8623
has
internal
RAMP
compensation to support low ESR MLCC output
capacitor solutions. The adaptive internal RAMP
is optimized so that the MPQ8623 is stable in the
entire operating input/output voltage range with
proper design of the output L/C filter.
FB
AGND
VREF
AMP
COMP
COMP
PWM
HS-FET
Driver
TON
LS-FET
Driver
IO
IL
HSFET
ON
Timer
+Σ
+
FB
REF
RAMP
Figure 3: Heavy-Load Operation (PWM)
VIN
PWM
Comparator
to minimize conduction loss. A dead short occurs
between VIN and PGND if both the HS-FET and
the LS-FET are turned on at the same time
(shoot-through). In order to avoid a shootthrough, a dead time (DT) is generated internally
between the HS-FET off and the LS-FET on
period or the LS-FET off and the HS-FET on
period.
PWM
Adaptive
RAMP
SW
L
Vsens+
LSFET
Vsens-
COUT
PGND
Figure 2: COT Control
PWM Operation
Figure 3 shows how the pulse-width modulation
(PWM) signal is generated. AMP corrects any
error between FB and REF and generates a
fairly smooth DC voltage (COMP). The internal
RAMP is superimposed onto COMP. The
superimposed COMP is compared with the FB
signal. Whenever FB drops below the
superimposed COMP, the integrated high-side
MOSFET (HS-FET) is turned on and remains on
for a fixed turn-on time. The fixed on time is
determined by the input voltage, output voltage,
and selected switching frequency. After the on
period elapses, the HS-FET turns off. The HSFET turns on again when FB drops below the
superimposed COMP. By repeating this
operation, the MPQ8623 regulates the output
voltage. The integrated low-side MOSFET (LSFET) turns on when the HS-FET is in its off state
CCM Operation
Continuous conduction mode (CCM) occurs
when the output current is high and the inductor
current is always above zero amps (see Figure
3). The MPQ8623 can also be configured to
operate in forced CCM operation when the
output current is low. See the Mode Selection
section on page 14 for details.
In CCM operation, the switching frequency is
fairly constant (PWM mode), so the output ripple
remains almost constant throughout the entire
load range.
Pulse-Skip Operation
At light-load condition, the MPQ8623 can be
configured to work in pulse-skip mode to
optimize efficiency. When the load decreases,
the inductor current decreases as well. Once the
inductor current reaches zero, the MPQ8623
transitions from CCM to pulse-skip mode if the
MPQ8623 is configured in this way. See the
Mode Selection section on page 14 for details.
MPQ8623 Rev. 1.01
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�MPQ8623 – 16V, 6A, HIGH EFFICIENCY SYNC STEP-DOWN CONVERTER W/ ADJUSTABLE CURRENT LIMIT
Figure 4 shows pulse-skip mode operation at
light-load condition. When FB drops below the
superimposed COMP, the HS-FET turns on for a
fixed interval. When the HS-FET turns off, the
LS-FET turns on until the inductor current
reaches zero. In pulse-skip mode operation, FB
does not reach the superimposed COMP when
the inductor current approaches zero. The LSFET driver turns into tri-state (high-Z) when the
inductor current reaches zero. A current
modulator takes over the control of the LS-FET
and limits the inductor current to less than
1mA. Therefore, the output capacitors discharge
slowly to PGND through the LS-FET. At lightload condition, the HS-FET is not turned on as
frequently in pulse-skip mode as it is in forced
CCM. As a result, the efficiency in pulse-skip
mode is improved greatly compared to that in
forced CCM operation.
The MPQ8623 enters PWM mode once the
output current exceeds the critical level.
Afterward, the switching frequency remains fairly
constant over the output current range.
The MPQ8623 can be configured to operate in
forced CCM even in light-load condition (see
Table 1).
Mode Selection
The MPQ8623 provides both forced CCM
operation and pulse-skip operation in light-load
condition. The MPQ8623 has three options for
switching frequency. Selecting the operation
mode under light-load condition and the
switching frequency is done by choosing the
resistance value of the resistor connected
between MODE and AGND or VCC (see Table
1).
Table 1: Mode Selection
MODE
REF
FB
RAMP
COMP
AGND
30.1kΩ (±20%)
to AGND
60.4kΩ (±20%)
to AGND
121kΩ (±20%)
to AGND
243kΩ (±20%)
to AGND
VCC
PWM
TON
HS-FET
Driver
LS-FET
Driver
Figure 4: Pulse Skip in Light Load
As the output current increases from the lightload condition, the time period the current
modulator regulates in becomes shorter. The
HS-FET is turned on more frequently, and the
switching frequency increases accordingly. The
output current reaches critical levels when the
current modulator time is zero. The critical level
of the output current can be determined with
Equation (1):
( VIN VOUT ) VOUT
2 L FSW VIN
Switching
Frequency
1100kHz
Forced CCM
2000kHz
Forced CCM
600kHz
Pulse skip
600kHz
Pulse skip
2000kHz
Pulse skip
1100Hz
Soft Start (SS)
The minimum soft-start time is limited to 1.5ms.
This can be increased by choosing the
capacitance between TRK/REF and AGND. A
minimum value of 3.3nF for this capacitor is
always required to stabilize the reference voltage.
IO
IL
IOUT
Light-Load
Mode
Forced CCM
The capacitance of this capacitor can be
determined with Equation (2) and Equation (3):
C REF (nF ) 3.3 ~ 17
CREF (nF )
(tSS = 1.5ms) (2)
tss (ms ) 10 A
(tSS > 1.5ms) (3)
0.9V
(1)
Where FSW is the switching frequency.
MPQ8623 Rev. 1.01
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�MPQ8623 – 16V, 6A, HIGH EFFICIENCY SYNC STEP-DOWN CONVERTER W/ ADJUSTABLE CURRENT LIMIT
Output Voltage Tracking and Reference
The MPQ8623 provides an analog input pin
(TRK/REF) to track another power supply or
accept an external reference voltage. When an
external voltage signal is connected to
TRK/REF, it acts as a reference for the
MPQ8623 output voltage. The FB voltage
follows this external voltage signal exactly, and
the soft-start settings are ignored. The TRK/REF
input signal can be in the range of 0.3V to 1.4V.
During the initial start-up, the TRK/REF must
reach 900mV or above first to ensure proper
operation. Afterward, TRK/REF can be set to any
value between 0.3V and 1.4V.
Pre-Bias Start-Up
The MPQ8623 has been designed for monotonic
start-up into pre-biased loads. If the output is
pre-biased to a certain voltage during start-up,
the IC disables switching for both the HS-FET
and LS-FET until the voltage on the TRK/REF
capacitor exceeds the sensed output voltage at
FB. Before the TRK/REF voltage reaches the
pre-biased FB level, if the BST voltage (from
BST to SW) is lower than 2.3V, the LS-FET is
turned on to allow the BST voltage to be charged
through VCC. The LS-FET is turned on for very
narrow pulses, so the drop in the pre-biased
level is negligible.
Output Voltage Discharge
When the MPQ8623 is disabled through EN, the
output voltage discharge mode is enabled. This
causes both the HS-FET and the LS-FET to latch
off. A discharge FET connected between SW
and PGND is turned on to discharge the output
voltage. The typical switch on resistance of this
FET is about 80Ω. Once the FB voltage drops
below 10%*REF, the discharge FET is turned off.
Current Sense and Over-Current Protection
(OCP)
The MPQ8623 features an on-die current sense
and a programmable positive current limit
threshold. The current limit is active when the
MPQ8623 is enabled. During the LS-FET on
state, the SW current (inductor current) is
sensed and mirrored to CS with the ratio of GCS.
By using a resistor (RCS) from CS to AGND, the
VCS voltage is proportional to the SW current
cycle-by-cycle. The HS-FET is only allowed to
turn on when the VCS voltage is below the internal
OCP voltage threshold (VOCP) during the LS-FET
on state to limit the SW valley current cycle-bycycle.
Calculate the current limit threshold setting from
RCS with Equation (4):
RCS ()
VOCP
(VIN VO ) VO
1
GCS (ILIM
)
VIN
2 L fs
(4)
Where VOCP = 1.2V, GCS = 40µA/A, and ILIM is the
desired output current limit.
If the MPQ8623 detects an over-current
condition for 31 consecutive cycles, or if FB
drops below the under-voltage protection (UVP)
threshold, it latches off. A power recycling of
VCC or EN is needed to enable the part again.
There is some offset for the low current limit
threshold setting. Refer to Table 2 for a more
accurate setting.
Table 2: Threshold Setting
LLIM_DC (A)
8
7.5
7
6.5
6
5.5
5
4.5
4
RCS (KΩ)
3.83
4.02
4.32
4.64
4.87
5.49
5.9
6.49
7.15
Negative Inductor Current Limit
When the LS-FET detects a -8A current, the
MPQ8623 turns off the LS-FET for 200ns to limit
the negative current.
Output Sinking Mode (OSM)
The MPQ8623 employs output sinking mode
(OSM) to regulate the output voltage to the
targeted value. When the FB voltage is higher
than 105%*REF but is below the OVP threshold,
OSM is triggered. During OSM operation, the
LS-FET remains on until it reaches the -4A
negative current limit. The LS-FET is then turned
off momentarily for 80ns and is turned on again.
The MPQ8623 repeats this operation until FB
drops below 102%*REF. The MPQ8623 exits
OSM after 15 consecutive cycles of forced CCM.
MPQ8623 Rev. 1.01
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�MPQ8623 – 16V, 6A, HIGH EFFICIENCY SYNC STEP-DOWN CONVERTER W/ ADJUSTABLE CURRENT LIMIT
Over-Voltage Protection (OVP)
The MPQ8623 monitors the output voltage by
connecting FB to the tap of the output voltage
feedback resistor divider to detect an overvoltage condition. This provides latch-off OVP
mode.
If the FB voltage exceeds 116% of the REF
voltage, the MPQ8623 enters latch-off OVP
mode. The HS-FET latches off and PGOOD
latches low until the power of VCC or EN are
recycled. Meanwhile, the LS-FET remains on
until it reaches the low-side negative current limit
(NOCP). The LS-FET is then turned off
momentarily for 80ns and is turned on again. The
MPQ8623 repeats this operation to bring down
the output voltage. When the FB voltage drops
below 50% of the REF voltage, the LS-FET is
turned off for pulse-skip mode and continues
turning on for forced CCM operation. If FB rises
back to more than 116% of the REF voltage, the
LS-FET turns on again with NOCP until FB drops
back below 50% of the REF voltage. The power
of EN or VIN must be recycled to clear the OVP
fault. The OVP function is enabled after
TRK/REF reaches 900mV.
Over-Temperature Protection (OTP)
The MPQ8623 has over-temperature protection
(OTP). The IC monitors the junction temperature
internally. If the junction temperature exceeds
the threshold value (typically 160°C), the
converter shuts off.
20kHz~60kHz. fZ can be determined with
Equation (6):
1
fZ
2 R1 CFF
(6)
Power Good (PGOOD)
The MPQ8623 has a power good (PGOOD)
output. PGOOD is the open-drain of a MOSFET.
Connect PGOOD to VCC or another external
voltage source less than 3.6V through a pull-up
resistor (10kΩ, typically). After applying the input
voltage, the MOSFET turns on, so PGOOD is
pulled to GND before TRK/REF is ready. After
the FB voltage reaches 92.5% of the REF
voltage, PGOOD is pulled high after a 0.8ms
delay.
When the FB voltage drops to 80% of the REF
voltage or exceeds 116% of the nominal REF
voltage, PGOOD is latched low. PGOOD can
only be pulled high again after a new SS.
If the input supply fails to power the MPQ8623,
PGOOD is clamped low, even though PGOOD is
tied to an external DC source through a pull-up
resistor. The relationship between the PGOOD
voltage and the pull-up current is shown in
Figure 5.
This is a latch-off protection. The power of VCC
or EN must be recycled to enable the MPQ8623
again.
Output Voltage Setting and Remote Output
Voltage Sensing
First, choose a value for R1. Then R2 can be
determined with Equation (5):
R2 (k)
VREF
R1(k)
VO VREF
(5)
Where VREF = 900mV.
To optimize the load transient response, a feedforward capacitor (CFF) is recommended to be in
parallel with R1. R1 and CFF add an extra zero to
the system, which improves loop response. R1
and CFF are selected so that the zero formed by
R1
and
CFF
is
located
around
Figure 5: PGOOD Clamped Voltage vs. Pull-Up
Current
Enable (EN) Configuration
The MPQ8623 turns on when EN goes high and
turns off when EN goes low. EN cannot be left
floating for proper operation. EN can be driven
by an analog or digital control logic signal to
enable or disable the MPQ8623.
MPQ8623 Rev. 1.01
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10/2/2018
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�MPQ8623 – 16V, 6A, HIGH EFFICIENCY SYNC STEP-DOWN CONVERTER W/ ADJUSTABLE CURRENT LIMIT
The MPQ8623 provides accurate EN thresholds,
so a resistor divider (R3/R4 in Figure 2) from VIN
to AGND can be used to program the input
voltage at which the MPQ8623 is enabled. This
is highly recommended for applications where
there is no dedicated EN control logic signal to
avoid possible UVLO bouncing during power-up
and power-down. The resistor divider values can
be determined with Equation (7):
VIN _ START ( V ) VIH EN
RUP RDOWN
R DOWN
(7)
Where VIHEN = 1.22V, typically.
RUP and RDOWN should be chosen so that VEN
does not exceed 3.6V when VIN reaches the
maximum value.
EN can also be connected to VIN directly
through a pull-up resistor (RUP). RUP should be
chosen so that the maximum current going to EN
is 50µA. RUP can be calculated with Equation (8):
RUP (k)
VIN MAX (V )
0.05(mA)
(8)
MPQ8623 Rev. 1.01
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�MPQ8623 – 16V, 6A, HIGH EFFICIENCY SYNC STEP-DOWN CONVERTER W/ ADJUSTABLE CURRENT LIMIT
APPLICATION INFORMATION
VOUT
Input Capacitor
The input current to the step-down converter is
discontinuous and therefore requires a capacitor
to supply AC current to the step-down converter
while maintaining the DC input voltage. Use
ceramic capacitors for the best performance.
During layout, place the input capacitors as close
to VIN as possible.
The capacitance can vary significantly with
temperature. Capacitors with X5R and X7R
ceramic dielectrics are recommended because
they are fairly stable over a wide temperature
range. The capacitors must have a ripple current
rating that exceeds the converter’s maximum
input ripple current. Estimate the input ripple
current with Equation (9):
VOUT
V
ICIN IOUT
(1 OUT )
VIN
VIN
(9)
The worst-case condition occurs at VIN = 2VOUT,
shown in Equation (10):
ICIN
IOUT
2
(10)
For simplification, choose an input capacitor with
an RMS current rating that exceeds half the
maximum load current.
The input capacitance value determines the
converter input voltage ripple. Select a capacitor
value that meets any input voltage ripple
requirements.
Estimate the input voltage ripple with Equation
(11):
VIN
IOUT
V
V
OUT (1 OUT )
FSW CIN
VIN
VIN
(11)
The worst-case condition occurs at VIN = 2VOUT,
with Equation (12):
VIN
IOUT
1
4 FSW CIN
(12)
VOUT
V
1
(1 OUT ) (R ESR
) (13)
FSW L
VIN
8 FSW C OUT
When using ceramic capacitors, the capacitance
dominates the impedance at the switching
frequency. The capacitance also dominates the
output voltage ripple. For simplification, estimate
the output voltage ripple with Equation (14):
VOUT
VOUT
8 FSW L COUT
2
(1
VOUT
) (14)
VIN
The ESR dominates the switching frequency
impedance for POSCAPs. For simplification, the
output ripple can be approximated with Equation
(15):
VOUT
VOUT
V
(1 OUT ) RESR
FSW L
VIN
(15)
Inductor
The inductor supplies a constant current to the
output load while being driven by the switching
input voltage. A larger value inductor results in
less ripple current and lower output ripple
voltage, but also has a larger physical size, a
higher series resistance, and a lower saturation
current. Generally, select an inductor value that
allows the inductor peak-to-peak ripple current to
be 30% to 40% of the maximum switch current
limit. Also design for a peak inductor current that
is below the maximum switch current limit.
Calculate the inductance value with Equation
(16):
L
VOUT
V
(1 OUT )
FSW IL
VIN
(16)
Where ∆IL is the peak-to-peak inductor ripple
current.
Choose an inductor that will not saturate under
the maximum inductor peak current. The peak
inductor current can be calculated with Equation
(17):
ILP IOUT
VOUT
V
(1 OUT )
2 FSW L
VIN
(17)
Output Capacitor
The output capacitor maintains the DC output
voltage. Use ceramic capacitors or POSCAPs.
Estimate the output voltage ripple with Equation
(13):
MPQ8623 Rev. 1.01
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�MPQ8623 – 16V, 6A, HIGH EFFICIENCY SYNC STEP-DOWN CONVERTER W/ ADJUSTABLE CURRENT LIMIT
PCB Layout Guidelines
Efficient PCB layout is critical for stable
operation. For the best performance, refer to
Figure 7 and follow the guidelines below.
5. Place the VCC decoupling capacitor close to
the device.
1. Place the input MLCC capacitors as close to
VIN and PGND as possible.
7. Place the BST capacitor as close to BST and
SW as possible.
2. Place the major MLCC capacitors on the
same layer as the MPQ8623.
8. Use traces with a width of 20mil or wider to
route the path.
3. Maximize the VIN and PGND copper plane
to minimize parasitic impedance.
9. Use a 0.1µF to 1µF bootstrap capacitor.
6. Connect AGND and PGND at the point of the
VCC capacitor's ground connection.
10. Place the REF capacitor close to TRK/REF
to AGND.
4. Place as many PGND vias as possible as
close to PGND as possible to minimize both
parasitic impedance and thermal resistance.
PGND
VCC
14
14
13
13
VOUT
12 MODE
12
PGND 1
SW 2
11
11
VIN 3
SW
10 BST
CS 4
VIN
SW
CVCC
9
EN 5
PGOOD
CBST
CIN1
CIN2
PGND
8 TRK/REF
6
7
FB
AGND
R2
CREF
R1
CFF
VOUT
Figure 7: Example of PCB Layout (Placement & Top Layer PCB)
NOTE: Via size is 20/10mils.
MPQ8623 Rev. 1.01
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10/2/2018
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�MPQ8623 – 16V, 6A, HIGH EFFICIENCY SYNC STEP-DOWN CONVERTER W/ ADJUSTABLE CURRENT LIMIT
PACKAGE INFORMATION
QFN-14 (2mmx3mm)
PIN 1 ID
PIN 1 ID
MARKING
PIN 1 ID
INDEX AREA
BOTTOM VIEW
TOP VIEW
SIDE VIEW
0.10x45°
NOTE:
1) LAND PATTERNS OF PIN1,5,8 AND PIN12 HAVE
THE SAME SHAPE.
2) LAND PATTERNS OF PIN2,4,9,10 AND PIN11 HAVE
THE SAME SHAPE.
3) ALL DIMENSIONS ARE IN MILLIMETERS.
3) LEAD COPLANARITY SHALL BE 0.10
MILLIMETERS MAX.
4) JEDEC REFERENCE IS MO-220.
5) DRAWING IS NOT TO SCALE.
RECOMMENDED LAND PATTERN
NOTICE: The information in this document is subject to change without notice. Please contact MPS for current specifications.
Users should warrant and guarantee that third party Intellectual Property rights are not infringed upon when integrating MPS
products into any application. MPS will not assume any legal responsibility for any said applications.
MPQ8623 Rev. 1.01
www.MonolithicPower.com
10/2/2018
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20
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