MIC24046 DATA SHEET (11/09/2015) DOWNLOAD

MIC24046
Pin-Programmable, 4.5V − 19V, 5A
Step-Down Converter
General Description
Features
The MIC24046 is a pin-programmable, high–efficiency,
wide input range, 5A synchronous step-down regulator.
The MIC24046 is perfectly suited for multiple-voltage rail
application environments typically found in computing and
telecommunication systems. It can be programmed by pin
strapping various parameters, such as output voltage,
switching frequency, and current-limit values. The pinselectable switching frequency, valley-current mode
control technique, high–performance error amplifier, and
external compensation allow for the best trade-offs
between high efficiency and the smallest possible solution
size.
•
•
•
•
The MIC24046 is available in a thermally–efficient, spacesaving, 20–pin 3mm × 3mm QFN package with an
operating junction temperature range of –40°C to +125°C.
Datasheets and support documentation are available on
Micrel’s website at: www.micrel.com.
•
•
•
•
•
•
•
4.5V to 19V input voltage range
5A (maximum) output current
High efficiency (>90%)
Pin-selectable output voltages:
− 0.7V, 0.8V, 0.9V, 1.0V, 1.2V, 1.5V, 1.8V,
2.5V, and 3.3V
±1% output voltage accuracy
Supports safe start-up with pre-biased output
Pin-selectable current limit and switching frequency
Internal soft-start and thermal shutdown protection
Hiccup-mode short-circuit protection
Available in a 20-pin 3mm × 3mm QFN package
–40°C to +125°C junction temperature range
Applications
• Servers, data storage, routers, and base stations
• FPGAs, DSP, and low-voltage ASIC power
Typical Application
MIC24046 12VIN 5A DC/DC Converter
Micrel Inc. • 2180 Fortune Drive • San Jose, CA 95131 • USA • tel +1 (408) 944-0800 • fax + 1 (408) 474-1000 • http://www.micrel.com
October 14, 2015
Revision 1.1
Micrel, Inc.
MIC24046
Ordering Information
Part Number
Junction Temperature Range
Package
Lead Finish
MIC24046YFL
–40°C to +125°C
20–Pin 3mm × 3mm QFN
Pb-Free
Pin Configuration
20–Pin 3mm × 3mm QFN (FL)
(Top View)
Pin Description
Pin Number
Pin Name
Pin Function
Input Voltage for the Buck Converter Power Stage: These pins are the drain terminal of the internal
high-side N-channel MOSFET. A 10 µF minimum ceramic capacitor should be connected from VIN to
PGND as close as possible to the device. A combination of multiple ceramic capacitors of different
sizes is recommended.
1−2
VIN
3 − 4, 13
PGND
5−6
LX
7
BST
Bootstrap: Supply voltage for the driver of the high-side N-channel power MOSFET. Connect the
bootstrap capacitor (top terminal) to this pin.
8
PG
Power Good (Output): When the output voltage is within 92.5% of the nominal set point, this pin will
go from logic low to logic high through an external pull-up resistor. This pin is the drain connection of
an internal N-channel FET.
9
VOSET0
Three-state Pin (Low, High, and High-Z) for Output Voltage Programming: Together with VOSET1,
VOSET0 defines nine logic values corresponding to nine output voltage selections.
10
VOSET1
Three-State Pin (Low, High, and High-Z) for Output Voltage Programming: Together with VOSET0,
VOSET1 defines nine logic values corresponding to nine output voltage selections.
October 14, 2015
Low-Side MOSFET Source Terminal and Low-Side Driver Return: Connect the ceramic input
capacitors to PGND as close as possible to the device.
Switch Node: Drain (low-side MOSFET) and source (high-side MOSFET) connection of the internal
power N-channel FETs. The external inductor (switched side) and bootstrap capacitor (bottom
terminal) must be connected to these pins.
2
Revision 1.1
Micrel, Inc.
MIC24046
Pin Description (Continued)
Pin Number
Pin Name
11
ILIM
12
FREQ
Three-State (Low, High, and High-Z) Switching Frequency Selection Pin.
14
AGND
Analog Ground: Quiet ground for the analog circuitry of the internal regulator and return terminal for
the external compensation network.
15
COMP
Transconductance Error Amplifier Output: Connect a compensation network from this pin to AGND.
16
OUTSNS
Output Sensing: Connect this pin directly to the buck converter output voltage. This pin is the top side
terminal of the internal feedback divider.
17
EN/DLY
Precision Enable/Turn-On Delay Input. The EN/DLY pin is first compared against a 507mV threshold
to turn-on the on-board LDO regulator. The EN/DLY pin is then compared against a 1.21V (typical)
threshold to initiate output power delivery. A 150mV typical hysteresis prevents chattering when
power delivery is started. A 2µA (typical) current source pulls up the EN/DLY pin. Turn-on delay can
be achieved by connecting a capacitor from EN/DLY to ground, while using an open-drain output to
drive the EN/DLY pin.
18
VDDA
Output of the internal linear regulator and internal supply for analog control. A 1µF minimum ceramic
capacitor should be connected from this pin to AGND; 2.2µF nominal value recommended.
19
VDDP
Internal Supply Rail for the MOSFET Drivers (fed by the VDDA pin): An internal resistor (10Ω)
between pins VDDP and VDDA is provided in the regulator in order to implement an RC filter for
switching noise suppression. A 1µF minimum ceramic capacitor should be connected from this pin to
PGND; 2.2µF nominal value recommended.
20
VINLDO
Input of the Internal Linear Regulator: This pin is typically connected to the input voltage of the buck
converter stage (VIN). If VINLDO and VIN are connected to different voltage rails, individually bypass
VINLDO to ground with a 100nF ceramic capacitor.
PGND_EP
PGND
VIN_EP
VIN
VIN Exposed Pad: Electrically connected to VIN pins. If an input power distribution plane is available,
connect with thermal vias to that plane to improve heat-sinking. Follow recommendations as
illustrated in the PCB Layout Recommendations section
LX_EP
LX
LX Exposed Pad: Electrically connected to LX pins. Follow recommendations as illustrated in the
PCB Layout Recommendations section
October 14, 2015
Pin Function
Three-State (Low, High, and High-Z) Current-Limit Selection Pin.
PGND Exposed Pad: Electrically connected to PGND pins. Connect with thermal vias to the ground
plane to ensure adequate heat-sinking. Follow recommendations as illustrated in the PCB Layout
Recommendations section
3
Revision 1.1
Micrel, Inc.
MIC24046
Absolute Maximum Ratings(1)
Operating Ratings(2)
VVIN, VVINLDO to AGND ................................... −0.3V to +20V
VVDDP, VVDDA to AGND ..................................... −0.3V to +6V
VVINLDO to VVDDA ............................................. −0.3V to +20V
VVDDP to VVDDA............................................... −0.3V to +0.3V
VVOSETx, VFREQ, VILIM, to AGND .........................−0.3V to +6V
VBST to VLX ....................................................... −0.3V to +6V
VBST to AGND ................................................ −0.3V to +26V
VEN/DLY to AGND ........................ −0.3V to VVDDA + 0.3V, +6V
VPG to AGND ................................................... −0.3V to +6V
VCOMP, VOUTSNS to AGND ........... −0.3V to VVDDA + 0.3V, +6V
AGND to PGND............................................ −0.3V to +0.3V
Junction Temperature .............................................. +150°C
Storage Temperature (TS) ......................... −65°C to +150°C
Lead Temperature (soldering, 10s) ............................ 260°C
(4)
ESD Rating
HBM ......................................................................... 2kV
MM ......................................................................... 150V
Supply Voltage (VVIN, VVINLDO) ........................... 4.5V to 19V
Externally Applied Analog and Drivers Supply Voltage
(VVINLDO = VVDDA = VVDDP) .................................. 4.5V to 5.5V
Enable Voltage (VEN/DLY) .................................... 0V to VVDDA
Power-Good (PG) Pull-up Voltage (VPU_PG) ........ 0V to 5.5V
Output Current ................................................................. 5A
Junction Temperature (TJ) ........................ −40°C to +125°C
Junction to Ambient Thermal Resistance
(3)
20-pin 3mm × 3mm QFN (θJA) ........................ 29°C/W
Electrical Characteristics(5)
VVIN = VVINLDO = 12V; CVDDA= 2.2µF, CVDDP = 2.2µF, TA = 25°C, unless otherwise noted. Bold values indicate −40°C ≤ TJ ≤ +125°C.
Symbol
Parameter
Test Conditions
Min.
Typ.
Max.
Units
19
V
0.2
2
µA
35
42
VIN Supply
4.5
VIN
Input Range
IVINQ
Disable Current
EN/DLY = 0V
IVINLDOQ
Disable Current
EN/DLY = 0V
IVINOp
Operating Current
EN/DLY > 1.28V, OUTSNS = 1.15 × VOUT(NOM),
no switching, TA = TJ = 25°C
0.45
0.75
mA
IVINLDOOp
Operating Current
EN/DLY > 1.28V, OUTSNS = 1.15 × VOUT(NOM),
no switching, TA = TJ = 25°C
5.6
7
mA
5.4
V
TA = TJ = 25°C
−40°C ≤ TJ ≤ +125°C
56
µA
VDDA 5V Supply
VDDA
Operating Voltage
EN/DLY > 0.58V, I(VDDA) = 0mA to 10mA
4.8
5.1
Dropout Operation
VINLDO = 4.5V, EN/DLY > 0.58V, I(VDDA) = 10mA
3.6
3.75
V
VDDA Undervoltage Lockout
UVLO_R
VDDA UVLO Rising
VVDDA Rising, EN/DLY > 1.28V
3.1
3.5
3.9
V
UVLO_F
VDDA UVLO Falling
VVDDA Falling, EN/DLY > 1.28V
2.87
3.2
3.45
V
UVLO_H
VDDA UVLO Hysteresis
300
mV
Notes:
1. Exceeding the absolute maximum ratings may damage the device.
2. The device is not guaranteed to function outside operating range.
3. θJA is measured on the MIC24046 evaluation board.
4. Devices are ESD sensitive. Handling precautions recommended. Human body model, 1.5kΩ in series with 100pF.
5. Specification for packaged product only.
October 14, 2015
4
Revision 1.1
Micrel, Inc.
MIC24046
Electrical Characteristics(5) (Continued)
VVIN = VVINLDO = 12V; CVDDA= 2.2µF, CVDDP = 2.2µF, TA = 25°C, unless otherwise noted. Bold values indicate −40°C ≤ TJ ≤ +125°C.
Symbol
Parameter
Test Conditions
Min.
Typ.
Max.
Units
507
580
mV
EN/DLY Control
EN_LDO_R
LDO Enable Threshold
Turns On VDDA LDO
EN_LDO_F
LDO Disable Threshold
Turns Off VDDA LDO
EN_LDO_H
LDO Threshold Hysteresis
EN_R
EN/DLY Rising Threshold
Initiates power-stage operation
EN_F
EN/DLY Falling Threshold
Stops power-stage operation
EN_H
EN/DLY Hysteresis
EN_I
EN/DLY Pull-Up Current
TA = TJ = 25°C
460
1.14
491
mV
16
mV
1.21
1.28
V
1.06
V
150
mV
1
2
3
µA
Switching Frequency
fSZ
Programmable Frequency
(High Z)
FREQ = High Z (open)
360
400
440
kHz
fS0
Programmable Frequency 0
FREQ = Low (GND)
500
565
630
kHz
fS1
Programmable Frequency 1
FREQ = High (VDDA)
700
790
880
kHz
Overcurrent Protection
ILIM_HS0
HS Current Limit 0
ILIM = Low (GND)
6.0
7.1
8.1
A
ILIM_HS1
HS Current Limit 1
ILIM = High (VDDA)
8.1
9.3
10.3
A
ILIM_HSZ
HS Current Limit High Z
ILIM = High Z (open)
9.3
10.5
11.9
A
LEB
Top FET Current-Limit
Leading Edge-Blanking Time
ILIM_LS0
LS Current Limit 0
ILIM = Low (GND)
3.0
4.6
6.3
A
ILIM_LS1
LS Current Limit 1
ILIM = High (VDDA)
4.0
6.2
7.9
A
ILIM_LSZ
LS Current Limit Hi Z
ILIM = High Z (Open)
5.0
6.8
8.6
A
INHICC_DE
OC Events Count for Hiccup
Number of subsequent cycles in
current limit before entering hiccup
overload protection.
15
tHICC_WAIT
Hiccup Wait Time
Duration of the High-Z state on LX
before new soft-start.
3x
Soft-Start
Time
108
ns
Clock
Cycles
Power Switches
RBOTTOM
Bottom FET ON resistance
VVIN = VVINLDO = VVDDP = VVDDA = 5V,
VBST-VLX = 5V, TA = TJ = 25°C
16
21
mΩ
RTOP
Top FET ON resistance
VVIN = VVINLDO = VVDDP = VVDDA = 5V,
VBST-VLX = 5V, TA = TJ = 25°C
38
50
mΩ
Minimum LX ON Time
TA = TJ = 25°C
26
TOFF(MIN)
Minimum LX OFF time
VVIN = VVINLDO = VVDDA = 5V, VOUTSNS =
3V, FREQ = Open (400kHz setting),
VVOSET0 = VVOSET1 = 0V (3.3V
setting),TA = TJ = 25°C
DMIN
Minimum Duty Cycle
VOUTSNS >1.1 × VOUT(NOM)
Pulse-Width Modulation (PWM)
TON(MIN)
October 14, 2015
5
90
135
0
ns
190
ns
%
Revision 1.1
Micrel, Inc.
MIC24046
Electrical Characteristics(5) (Continued)
VVIN = VVINLDO = 12V; CVDDA= 2.2µF, CVDDP = 2.2µF, TA = 25°C, unless otherwise noted. Bold values indicate −40°C ≤ TJ ≤ +125°C.
Symbol
Parameter
Test Conditions
Min.
Typ.
Max.
Units
Gm Error Amplifier
GmEA
Error-Amplifier
Transconductance
AEA
Error-Amplifier DC Gain
ISR_SNK
Error-Amplifier
Source/Sink Current
COMP_H
COMP Output Swing High
2.4
V
COMP_L
COMP Output Swing Low
0.8
V
GmPS
COMP-to-Inductor Current
Transconductance
12.5
A/V
1.5
mmho
50000
V/V
−400
VOUT = 1.2V, IOUT = 4A
+400
µA
Output Voltage DC Accuracy
OutErr12
Output Voltage Accuracy for
Ranges 1 and 2
OutErr3
Output Voltage Accuracy for
Range 3
4.75V ≤ VIN ≤ 19V, VOUT = 0.7V to 1.8V
TA = TJ = −40°C to 125°C, IOUT = 0A
4.75V ≤ VIN ≤ 19V, VOUT = 2.49V to
3.3V
−1
1
%
−1.5
1.5
%
TA = TJ = −40°C to 125°C, IOUT = 0A
LoadReg
Load Regulation
IOUT = 0A to 5A
0.25
%
LineReg
Line Regulation
6V< VIN < 19V, IOUT = 2A
0.1
%
VOUT = 0.7V, 0.8V, 0.9V, 1.0V, 1.2V
0.45
V/ms
0.18
0.4
V
Internal Soft-Start
SS_SR
Reference Soft-Start Slew
Rate
Power Good (PG)
PG_VOL
PG Low Voltage
I(PG)=4mA
PG_ILEAK
PG Leakage Current
VPG =5V
-1
0.02
1
µA
PG_R
PG Rise Threshold
VOUT Rising
90
92.5
95
%
PG_F
PG Fall Threshold
VOUT Falling
87.5
90
92.5
%
PG_R_DLY
PG Rise Delay
VOUT Rising
0.45
ms
PG_F_DLY
PG Fall Delay
VOUT Falling
70
µs
Thermal Shutdown
TSHDN
Thermal Shutdown
160
°C
TSHDN_HYST
Thermal-Shutdown Hysteresis
25
°C
82.3
%
Efficiency
η
Efficiency
October 14, 2015
VIN = 12V, VOUT = 0.9V, IOUT = 2A
fS = fSZ = 400kHz, L = 1.2µH, TA = 25°C
6
Revision 1.1
Micrel, Inc.
MIC24046
Typical Characteristics
VVIN = VVINLDO = 12V; CVDDA= 2.2µF, CVDDP = 2.2µF, TA = 25°C, unless otherwise noted.
VDD Voltage
vs. Input Voltage
Operating Current (IQ)
vs. Input Voltage
5.3
LOW-SIDE CURRENT LIMIT (A)
5.1
18
f = 790kHz
17
16
f = 565kHz
15
14
13
f = 400kHz
12
Switching
VOUT = 1.0V
IOUT = 0A
11
4.9
IVDDA = 10mA
4.7
4.5
4.3
4.1
10
6
8
10
12
14
16
18
6
10
8
12
14
16
18
5
ILIM = GND
VOUT = 1.2V
L = 2.2µH
4
4
6
8
10
12
14
16
INPUT VOLTAGE (V)
Enable Threshold
vs. Input Voltage
EN/DLY Pull-up Current
vs. Input Voltage
Operating Current (IQ)
vs. Temperature
3
20
2.8
19
EN/DLY (µA)
1.2
ENABLE RISING
1.1
1.05
2.4
2.2
2
1.8
1.6
ENABLE FALLING
1.4
0.95
10
12
14
16
18
20
4
6
8
INPUT VOLTAGE (V)
f = 790kHz
17
16
f = 565kHz
15
14
13
12
SWITCHING
VIN = 12V
VOUT = 1.0V
IOUT = 0A
f = 400kHz
10
12
14
16
18
-40 -20
20
INPUT VOLTAGE (V)
FET ON Resistance
vs. Temperature
0
20
40
60
80 100 120 140
TEMPERATURE (°C)
EA Output Current
vs. Temperature
EA Transconductance
vs. Temperature
65
20
10
1
8
18
18
11
EN/DLY = 0V
1.2
0.9
6
ILIM = VDDA
6
20
2.6
4
7
INPUT VOLTAGE (V)
1.25
1
ILIM = Hi-Z
8
INPUT VOLTAGE (V)
1.3
1.15
9
3
4
20
OPERATING CURRENT (mA)
4
800
55
RTOP
45
35
25
RBOTTOM
15
VIN = 12V
5
EA TRANSCONDUCTANCE (mS)
2
1.8
1.6
1.4
1.2
1
VIN = 12V
VOUT = 1.0V
0.8
-20
0
20
40
60
80
100 120 140
TEMPERATURE (°C)
October 14, 2015
600
400
200
SINKING
0
-200
SOURCING
-400
-600
VIN = 12V
-800
0.6
-40
EA OUTPUT CURRENT (µA)
ENABLE THRESHOLD (V)
10
IVDDA = 0mA
19
VDD VOLTAGE (V)
OPERATING CURRENT (mA)
20
FET ON RESISTANCE (mΩ)
Low-Side Current Limit
vs. Input Voltage
-40
-20
0
20
40
60
80
100 120 140
TEMPERATURE (°C)
7
-40
-20
0
20
40
60
80
100 120 140
TEMPERATURE (°C)
Revision 1.1
Micrel, Inc.
MIC24046
Typical Characteristics (Continued)
VVIN = VVINLDO = 12V; CVDDA= 2.2µF, CVDDP = 2.2µF, TA = 25°C, unless otherwise noted.
Efficiency (VIN = 5.0V)
vs. Output Current
0.91
90
90
0.905
80
70
VOUT = 3.3V
VOUT = 2.5V
VOUT = 1.8V
VOUT = 1.5V
VOUT = 1.2V
VOUT = 1.0V
VOUT = 0.9V
VOUT = 0.8V
VOUT = 0.7V
60
VIN = 12V
L = 2.2µH
80
70
VOUT = 3.3V
VOUT = 2.5V
VOUT = 1.8V
VOUT = 1.5V
VOUT = 1.2V
VOUT = 1.0V
VOUT = 0.9V
VOUT = 0.8V
VOUT = 0.7V
60
50
1
2
3
4
5
2
1
3
4
5
6
0
1
0.995
0.99
VIN = 12V
VOUT = 1.0V
1.205
1.2
1.195
1.19
VIN = 12V
VOUT = 1.2V
4
1.505
1.5
1.495
1.49
1
2
3
4
OUTPUT CURRENT (A)
OUTPUT CURRENT (A)
Output Voltage (VOUT = 1.8V)
vs. Output Current
Output Voltage (VOUT = 2.5V)
vs. Output Current
5
0
2.51
3.32
1.79
VIN = 12V
VOUT = 1.8V
1.785
OUTPUT VOLTAGE (V)
3.33
OUTPUT VOLTAGE (V)
2.52
1.795
2.5
2.49
2.48
2.47
VIN = 12V
VOUT = 2.5V (2.49V)
2.46
0
1
2
3
4
OUTPUT CURRENT (A)
October 14, 2015
5
3
4
5
3.31
3.3
3.29
3.28
3.27
2.45
1.78
2
Output Voltage (VOUT = 3.3V)
vs. Output Current
1.82
1.8
1
OUTPUT CURRENT (A)
1.815
1.805
VIN = 12V
VOUT = 1.5V
1.48
0
5
1.81
5
1.51
1.485
1.18
3
4
1.52
1.185
0.98
3
1.515
OUTPUT VOLTAGE (V)
OUTPUT VOLTAGE (V)
1.005
2
Output Voltage (VOUT = 1.5V)
vs. Output Current
1.21
2
1
OUTPUT CURRENT (A)
Output Voltage (VOUT = 1.2V)
vs. Output Current
1.01
1
VIN = 12V
VOUT = 0.9V
OUTPUT CURRENT (A)
Output Voltage (VOUT = 1.0V)
vs. Output Current
0
0.89
0.88
0
6
OUTPUT CURRENT (A)
0.985
0.895
0.885
40
0
0.9
VIN = 5.0V
L = 2.2µH
40
OUTPUT VOLTAGE (V)
OUTPUT VOLTAGE (V)
100
50
OUTPUT VOLTAGE (V)
Output Voltage (VOUT = 0.9V)
vs. Output Current
100
EFFICIENCY (%)
EFFICIENCY (%)
Efficiency (VIN = 12V)
vs. Output Current
VIN = 12V
VOUT = 3.3V
3.26
0
1
2
3
4
OUTPUT CURRENT (A)
8
5
0
1
2
3
4
5
OUTPUT CURRENT (A)
Revision 1.1
Micrel, Inc.
MIC24046
Functional Characteristics
VVIN = VVINLDO = 12V; CVDDA= 2.2µF, CVDDP = 2.2µF, TA = 25°C, unless otherwise noted.
October 14, 2015
9
Revision 1.1
Micrel, Inc.
MIC24046
Functional Characteristics (Continued)
VVIN = VVINLDO = 12V; CVDDA= 2.2µF, CVDDP = 2.2µF, TA = 25°C, unless otherwise noted.
October 14, 2015
10
Revision 1.1
Micrel, Inc.
MIC24046
Functional Characteristics (Continued)
VVIN = VVINLDO = 12V; CVDDA= 2.2µF, CVDDP = 2.2µF, TA = 25°C, unless otherwise noted.
October 14, 2015
11
Revision 1.1
Micrel, Inc.
MIC24046
Functional Diagram
October 14, 2015
12
Revision 1.1
Micrel, Inc.
MIC24046
possible to the IC. A combination of ceramic capacitors of
different sizes is recommended.
Functional Description
The MIC24046 is a pin-programmable, 5A valley currentmode controlled regulator featuring an input voltage
range from 4.5V to 19V.
An internal LDO (input = VINLDO) provides a clean
voltage supply (5.1V typ.) for the analog circuits at pin
VDDA. The internal LDO is typically powered from the
same power rail feed as VIN; however, VINLDO can also
be higher or lower than VIN, and can be connected to
any other voltage within its recommended limits. VINLDO
and VDDA should be locally bypassed (see Pin
Description). A small series resistor (typically 2Ω-10Ω)
can be used in combination with the VINLDO bypass
capacitor to implement a RC filter for suppression of large
high-frequency switching noise.
The MIC24046 requires a minimal amount of external
components. Only the inductor, supply decoupling
capacitors, and compensation network are external. The
flexibility in the external compensation design allows the
user to optimize their design across the entire input
voltage and selectable output voltages range.
Theory of Operation
Valley-current-mode control is a fixed-frequency, leadingedge modulated PWM current-mode control. Differing
from the peak-current-mode, the valley-current-mode
clock marks the turn-off of the high-side switch. Upon this
instant, the MIC24046 low-side switch current level is
compared against the reference current signal from the
error amplifier. When the falling low-side switch current
signal drops below the current reference signal, the high
side switch is turned on. As a result, the inductor valley
current is regulated to a level dictated by the output of the
error amplifier.
The internal LDO is enabled when the voltage at the
EN/DLY pin exceeds about 0.51V, and regulation takes
place as soon as enough voltage has established
between the VINLDO and VDDA pins. If an external
5V±10% is available, it is possible to bypass the internal
LDO by connecting VINLDO, VDDA and VDDP together
at the external 5V rail, thus improving overall efficiency.
An internal undervoltage lock-out circuit (UVLO) monitors
the level of VDDA.
VDDP is the power supply rail for the gate drivers and
bootstrap circuit. This pin is subject to high-current spike
with high-frequency content. To prevent these from
polluting the analog VDDA supply, a separate capacitor is
needed for VDDP pin bypassing.
As shown in the, “Compensation Design” sub-section
within the Application Information section, the feedback
loop includes an internal programmable reference
(REFDAC) and output voltage sensing attenuator (R2/R1),
which removes the need for external feedback
components and improves regulation accuracy. Output
voltage feedback is achieved by connecting OUTSNS
directly to
the
output.
The
high-performance
transconductance error amplifier drives an external
compensation network at the COMP pin. The COMP pin
voltage represents the reference current signal. The
COMP pin voltage is fed to the valley-current-mode
modulator, which also adds slope compensation to
guarantee current-loop stability. Valley-current-mode
control requires slope compensation at duty cycles less
than 50% for current-loop stability. The slope
compensation circuit is internal, and it is automatically
adapted in amplitude depending upon the frequency,
output voltage range, and voltage differential (VVIN −
VOUTSNS). The internal low-RDS(ON) power MOSFETs,
associated adaptive gate driver, and internal bootstrap
diode complete the power train.
An internal 10Ω resistor is provided between VDDA and
VDDP allowing a switching noise attenuation RC filter
with the minimum amount of external components to be
implemented. It is possible − although typically not
necessary − to lower the RC time constant by connecting
an external resistor between VDDA and VDDP.
Pin-strapping Programmability (VOSET0, VOSET1,
FREQ, ILIM)
The MIC24046 uses pin-strapping to set the output
voltage (pins VOSET0, VOSET1), switching frequency
(pin FREQ), and current limit (pin ILIM). No external
passives are needed, such that external component
count is minimized. Each pin is a three-state input
(connect to GND for LOW logic level, connect to VDDA
for HIGH logic level or leave unconnected for high-Z).
The logic level of the pins is read and frozen in the
internal configuration logic immediately after the VDDA
rail has come up and stabilized. After this instant, any
change of the input logic level on the pins will have no
effect until the VDDA power is cycled again. The values
corresponding
to
each
particular
pin-strapping
configuration are detailed in the Application Information
section.
Overcurrent protection and thermal shutdown protect the
MIC24046 from faults or abnormal operating conditions.
Internal LDO, Supply Rails
(VIN, VINLDO, VDDA, VDDP)
VIN represents the power train input. These pins are the
drain connection of the internal high-side MOSFET and
should be bypassed to GND with an X5R or X7R 10µF
(minimum) ceramic capacitor, placed as close as
October 14, 2015
13
Revision 1.1
Micrel, Inc.
MIC24046
Enable/Delay (EN/DLY)
EN/DLY is a dual-threshold pin that turns the internal
LDO on and off, and starts/stops the power delivery to
the output. This is shown in Figure 1:
more, depending on the selected output voltage value),
therefore its loading effect is typically negligible.
OUTSNS is also used by the slope compensation
generator.
COMP is the connection for the external compensation
network. COMP is driven by the output of the
transconductance error amplifier. Care must be taken to
return the compensation network ground directly to
AGND.
Soft-Start
The MIC24046 internal reference is ramped up at a
0.45V/ms rate. Note that this is the internal reference
soft-start slew rate and that the actual slew rate seen at
the output should take into account the internal divider
attenuation as detailed in the Application Information
section.
Switching Frequency (FREQ)
The MIC24046 features three different selectable
switching frequencies: 400kHz, 565kHz, and 790kHz.
Figure 1. EN/DLY Pin Functionality
The threshold for power delivery (EN_R) is a precise
1.21V ±70mV. A 150mV typical hysteresis prevents
chattering due to switching noise and/or slow edges.
Pre-Biased Output Start-Up
The MIC24046 is designed to achieve safe start-up into a
pre-biased output without discharging the output
capacitors.
A 2µA typical pull-up current with ±1µA accuracy permits
the implementation of a start-up delay by means of an
external capacitor. In this case, it is necessary to use an
open-drain driver to disable the MIC24046 while
maintaining the start-up delay function.
Thermal Shutdown
The MIC24046 has thermal-shutdown protection that
prevents operation at excessive temperature. The
thermal-shutdown threshold is typically set at 160°C with
a hysteresis of 25°C.
Power-Good (PG)
PG is an open-drain output that requires an external pullup resistor to a pull-up voltage (VPU_PG) less than 5.5V for
being asserted to a logic HIGH level. PG is asserted with
a typical delay of 0.45ms when the output voltage
(OUTSNS) reaches 92.5% of its target regulation voltage.
PG is de-asserted with a typical delay of 70µs when the
output voltage falls below 90% of its target regulation
voltage. The PG falling delay acts as a de-glitch timer
against very short spikes. The PG output is always
immediately de-asserted when the EN/DLY pin is below
the power delivery enable threshold (EN_R/EN_F). The
pull-up resistor should be large enough to limit the PG pin
current to below 2mA.
Overcurrent Protection (ILIM) and Hiccup Mode
Short-Circuit Protection
The MIC24046 features instantaneous cycle-by-cycle
current limit with current sensing on both low-side and
high-side switches. It also offers a hiccup mode for
prolonged overloads or short-circuit conditions.
Low-side cycle-by-cycle protection detects the current
level of the inductor current during the low-side MOSFET
ON time. The high-side MOSFET turn-on is inhibited as
long as the low-side MOSFET current limit is above the
current-limit threshold level. The inductor current will
continue decaying until the current falls below the
threshold, where the high-side MOSFET will be enabled
again according to the duty cycle requirement from the
PWM modulator. The mechanism is illustrated in Figure
2.
Inductor (LX) and Bootstrap (BST)
The external inductor is connected to LX. The high-side
MOSFET driver circuit is powered between BST and LX
by means of an external capacitor (typically 100nF) that
is replenished from rail VDDP during the low-side
MOSFET ON-time. The bootstrap diode is internal.
Output Sensing (OUTSNS) and Compensation
(COMP)
OUTSNS should be connected exactly to the desired
point-of-load regulation avoiding parasitic resistive drops.
The impedance seen into OUTSNS is high (tens of kΩ or
October 14, 2015
14
Revision 1.1
Micrel, Inc.
MIC24046
Hiccup mode protection reduces power dissipation in
permanent short-circuit conditions. On each clock cycle
where a low-side cycle-by-cycle current-limit event is
detected, a 4-bit up/down counter is incremented. On
each clock cycle, without a concurrent low-side current
limit event, the counter is decremented or left at zero.
The counter cannot wrap-around below 0000 and above
1111. High-side current limit events do not increment the
counter. Only detections from low-side current limit
events trigger the counter.
If the counter reaches 1111 (or 15 events), the high- and
low-side MOSFETs become tri-stated, and power
delivery to the output is inhibited for the duration of three
times the soft-start time. This digital integration
mechanism provides immunity to momentary overloading
of the output. After the wait time, the MIC24046 retries
entering operation and initiates a new soft-start
sequence.
Figure 2. Low-Side Cycle-by-Cycle Current-Limit Action
The low-side current limit has three different
programmable levels (for 3A, 4A, and 5A loads), in order
to fit different application requirements. Since the lowside current limit acts on the valley current, the DC output
current level (IOUT) where the low-side cycle-by-cycle
current limit is engaged will be higher than the current
limit value by an amount equal to ΔILPP/2, where ΔILPP is
the peak-to-peak inductor ripple current.
Figure 3 illustrates the hiccup mode short-circuit
protection logic flow. Note that hiccup mode short-circuit
protection is active at all times, including the soft-start
ramp.
The high-side current limit is approximately 1.4 − 1.5
times greater than the low-side current limit (typical
values). The high-side cycle-by-cycle current limit
immediately truncates the high-side ON time without
waiting for the OFF clocking event.
A leading edge blanking (LEB) timer (108ns, typical) is
provided on the high-side cycle-by-cycle current limit to
mask the switching noise and to prevent falsely triggering
the protection. High-side cycle-by-cycle current limit
action cannot take place before the LEB timer expires.
October 14, 2015
15
Revision 1.1
Micrel, Inc.
MIC24046
Figure 3. Hiccup Mode Short-Circuit Protection Logic
October 14, 2015
16
Revision 1.1
Micrel, Inc.
MIC24046
Application Information
The programmed VIN UVLO threshold VIN_RISE is given by:
Programming Start-Up Delay and External UVLO
The EN/DLY pin allows programming of an external startup delay. In this case, the driver for the EN/DLY pin
should be an open-drain/open-collector type as shown in
Figure 4:
R2 

VIN _ RISE = EN _ R ×  1 +
 − EN _ I × R2
R1 

Eq. 2
where:
EN_R = 1.21V
EN_I = 2µA
R1 and R2 = External resistors.
To desensitize the VIN UVLO threshold against variations
of the pull-up current EN_I, it is recommended to run the
R1 − R2 voltage divider at a significantly higher current
level than the EN_I current.
The corresponding VIN UVLO hysteresis VIN_HYS is
calculated as follows:
Figure 4. Programmable Start-Up Delay Function
R2 

VIN _ HYS = 150mV ⋅  1 +

R1 

The start-up delay is the delay time from the OFF falling
edge to the assertion of the enable power delivery signal
and can be calculated as shown in Equation 1:
EN _ R × CDLY
t SU _ DLY =
EN _ I
Eq. 3
Similar calculations also apply to the internal LDO
activation threshold.
Eq. 1
Setting the Switching Frequency
The MIC24046 switching frequency can be programmed
using FREQ as shown in Table 1:
where:
Table 1. Switching Frequency Settings
EN_R = 1.21V
EN_I = 2µA
FREQ
Frequency
Hi-Z (open)
400kHz
CDLY = Delay programming external capacitor
0 (GND)
565kHz
The EN/DLY pin can also be used to program an UVLO
threshold for power delivery by means of an external
resistor divider, as described in the following Figure 5.
1 (VDDA)
790kHz
Figure 5. Programmable External UVLO Function
October 14, 2015
17
Revision 1.1
Micrel, Inc.
MIC24046
Setting the Output Voltage
The MIC24046 output voltage can be programmed by
setting pins VOSET0 and VOSET1, as shown in Table 2.
Ensure the value of the operating junction temperature
does not exceed the maximum rating in high output
power applications.
Table 2. Output Voltage Settings
Inductor Selection and Slope Compensation
When selecting an inductor, it is important to consider the
following factors:
VOSET1
VOSET0
Output Voltage
0 (GND)
0 (GND)
3.3V
0 (GND)
1 (VDDA)
2.5V (2.49V)
1 (VDDA)
0 (GND)
1.8V
1 (VDDA)
1 (VDDA)
1.5V
0 (GND)
Hi-Z (Open)
1.2V
Hi-Z (Open)
0 (GND)
1.0V
1 (VDDA)
Hi-Z (Open)
0.9V
Hi-Z (Open)
1 (VDDA)
0.8V
Hi-Z (Open)
Hi-Z (Open)
0.7V
•
•
•
•
•
Inductance
Rated current value
Size requirements
DC resistance (DCR)
Core losses
The inductance value is critical to the operation of
MIC24046. Since the MIC24046 is a valley current-mode
regulator, it needs a slope compensation for the stable
current loop operation where duty cycles are below 50%.
Slope compensation is internally programmed according
to the frequency and output voltage selection, assuming
there is a minimum inductance value for the given
operating condition. Table 4 lists the assumed minimum
inductor values recommended for stable current loop
operation. Note that the minimum suggested inductance
values should be met when taking into account inductor
tolerance and its change with current level.
To achieve accurate output voltage regulation, the
OUTSNS pin (internal feedback divider top terminal)
should be Kelvin-connected as close as possible to the
point-of-regulation top terminal. Since both the internal
reference and the internal feedback divider’s bottom
terminal refer to AGND, it is important to minimize voltage
drops between the AGND and the point-of-regulation
return terminal.
Table 4. Recommended Inductance Values at VIN = 12V
Setting the Current Limit
The MIC24046 valley-mode current limit on the low-side
MOSFET can be programmed by means of ILIM as
shown in Table 3.
VOUT
SELECTION
0.7V, 0.8V, 0.9V,
1.0V, 1.2V
Table 3. Current-Limit Setting
FREQUENCY
MINIMUM
INDUCTANCE
400kHz
0.97
565kHz
0.68
790kHz
0.49
400kHz
1.51
565kHz
1.06
Low-Side Valley
Current Limit
(Typical Value)
Rated Output
Current
0 (GND)
4.6 A
3A
790kHz
0.76
1 (VDDA)
6.2 A
4A
400kHz
2.42
Hi-Z (Open)
6.8 A
5A
565kHz
1.70
790kHz
1.21
ILIM
1.5V, 1.8V
2.49V, 3.3V
Note that the programmed current-limit values act as
pulse-by-pulse current-limit thresholds on the valley
inductor current. If the inductor current has not decayed
below the threshold at the time the PWM requires a new
ON time, the high-side MOSFET turn-on is either delayed
until the valley current recovers below the threshold or
skipped. Each time the high-side MOSFET turn-on is
skipped, a 4-bit up-down counter is incremented. When
the counter reaches the configuration 1111, a hiccup
sequence is invoked in order to reduce power dissipation
under prolonged short-circuit conditions.
The slope compensation is also internally adapted to the
input-output voltage differential.
In practical implementations of valley-current-mode
control, slope compensation is also added to any duty
cycle larger than 50% as part of improving current loop
stability and noise immunity for all input and output
voltage ranges. Consequently, the MIC24046 adds
internal slope compensation signal up to 60% duty cycle.
Above this, no slope compensation is added. For this
reason, the PWM modulator gain exhibits an abrupt
change when the duty cycle exceeds 60%, possibly
leading to some increase in jitter and noise susceptibility.
The highest current-limit setting (6.8A) is intended to
comfortably accommodate a 5A application.
October 14, 2015
18
Revision 1.1
Micrel, Inc.
MIC24046
If operation around and above 60% duty cycle is
considered, a more conservative design of the
compensation loop might help in reducing jitter and noise
sensitivity.
inductor current ripple and the peak inductor current can
be calculated as:
 1 − VO /VIN 

∆IL_PP = VO 
 fS × L 
Inductor current ratings are generally stated as
permissible DC current and saturation current.
Permissible DC current can be rated for a 20°C to 40°C
temperature rise. Saturation current can be rated for a
10% to 30% loss in inductance. Ensure that the nominal
current of the application is well within the permissible DC
current ratings of the inductor, depending on the allowed
temperature rise. Note that the inductor permissible DC
current rating typically does not include inductor core
losses. These are very important contributors of total
inductor core loss and temperature increase in highfrequency DC/DC converters because core losses
increase rapidly with the excitation frequency.
IL, PEAK = IO +
∆VR, C =
ESR
Eq. 7
8 × fs × C O
output
∆VR ≅ ∆VR, C + ∆VR, ESR
Eq. 8
ripple
is
then
Eq. 9
The output capacitor value and ESR should be chosen so
ΔVR is within specifications. Capacitor tolerance should
be considered for worst case calculations. In the case of
ceramic output capacitors, factor into account the
decrease of effective capacitance versus applied DC
bias.
The worst-case load transient for output capacitor
calculation is an instantaneous 100% to 0% load release
when the inductor current is at its peak value. In this
case, all the energy stored in the inductor is absorbed by
the output capacitor while the converter stops switching
and keeps the low-side FET ON.
As shown in Equation 4, the peak inductor current is
inversely proportional to the switching frequency and the
inductance. The lower the switching frequency or
inductance, the higher the peak current. As input voltage
increases, the peak current also increases.
The peak output voltage overshoot (ΔVOUT) happens
when the inductor current has decayed to zero. This can
be calculated with Equation 10:
and
• Steady-state ripple
• Maximum voltage deviation during load transient
ΔVO = VO2 +
For steady-state ripple calculation, the ESR and the
capacitive ripple both contribute to the total ripple
amplitude.
L 2
− VO
I
C O L, PEAK
Eq. 10
Equation 11 calculates the minimum output capacitance
value (CO(MIN)) needed to limit the output overshoot below
ΔVOUT.
From the switching frequency, input voltage, output
voltage setting, and load current, the peak-to-peak
October 14, 2015
∆IL_PP
The total peak-to-peak
conservatively estimated as:
Eq. 4
size
Eq. 6
2
∆VR, ESR = ESR × ∆IL_PP
Pay attention to the inductor saturation characteristic in
current limit. The inductor should not heavily saturate,
even in current limit operation. If there is heavy
saturation, the current may instantaneously run away and
reach potentially destructive levels. Typically, ferrite-core
inductors exhibit an abrupt saturation characteristic, while
powdered-iron or composite inductors have a softsaturation characteristic. Peak current can be calculated
with Equation 4.
Output Capacitor Selection
Two main requirements determine the
characteristics of the output capacitor CO:
∆IL_PP
The capacitive ripple ΔVR, C and the ESR ripple ΔVR,
are given by:
When saturation current is specified, make sure that
there are enough design margins so the peak current
does not cause the inductor to enter deep saturation.

 1 − VO /VIN 
IL, PEAK = IO + VO 

 2 × f × L 

Eq. 5
19
Revision 1.1
Micrel, Inc.
C O(MIN) =
MIC24046
2
L × IL,
PEAK
removed and the power-stage transfer function from
COMP to the inductor current is modeled as a
transconductance (GmPS). The simplified model of the
control loop is shown in Figure 6. The power-stage
transconductance GmPS shows some dependence on
current levels and it is also somewhat affected by
process variations, therefore some design margin is
recommended against the typical value GmPS = 12.5 A/V
)
(see Electrical Characteristics(5 ).
Eq. 11
(ΔVO + VO )2 − VO2
The result from the minimum output capacitance value for
load transient is the most stringent requirement found for
capacitor value in most applications. Low equivalent
series resistance (ESR) ceramic output capacitors with
X5R
or
X7R
temperature
characteristics
are
recommended.
For low output voltage applications with demanding load
transient requirements, using a combination of polarized
and ceramic output capacitors may be most convenient
for smallest solution size.
Input Capacitor Selection
Two main requirements determine
characteristics of the input capacitor:
the
size
and
• Steady-state ripple
• RMS current
Figure 6. Simplified Small-Signal Model
of the Voltage Regulation Loop
The buck converter input current is a pulse train with very
fast rising and falling times so low-ESR ceramic
capacitors are recommended for input filtering, because
of their good high-frequency characteristics.
This simplified approach disregards all issues related to
the inner current loop, like its stability and bandwidth.
This approximation is good enough for most operating
scenarios, where the voltage-loop bandwidth is not
pushed to aggressively high frequencies.
For ideal input filtering (assuming a DC input current
feeding the filtered buck power stage), and by neglecting
the capacitor ESR contribution to the input ripple
(typically possible for ceramic input capacitors), the
minimum capacitance value CIN(MIN) needed for a given
input peak-to-peak ripple voltage ΔVr, IN can be estimated
as shown in Equation 12:
CIN(MIN) =
IO × D × (1 − D)
DVr,IN × fS
Based on the model shown in Figure 6, the control-tooutput transfer function is:
Eq. 12
GCO(S) =
where:
VO(S)
VC(S)
= GmPS
D is the duty cycle at the given operating point.
The RMS current IIN,RMS of the input capacitor is estimated
as in Equation 13:
IIN, RMS = IO × D × (1 - D)
Eq. 14
where:
fZ and fP = The frequencies associated with the output
capacitor ESR zero and with the load pole, respectively:
Eq. 13
Note that for a given output current IO, the worst case
values are obtained at D = 0.5.
fZ =
Multiple input capacitors can be used to reduce input
ripple amplitude and/or individual capacitor RMS current.
Compensation Design
As a simple first-order approximation, the valley-currentmode-controlled buck power stage can be modeled as a
voltage-controlled current-source feeding the output
capacitor and load. The inductor current state-variable is
October 14, 2015

s 
 1 +

2π × f Z 

× RL ×

s 
 1 +

2
π
× fP 

fP =
20
1
2π × C O × ESR
1
2π × C O × (ESR + R L )
Eq. 15
Eq. 16
Revision 1.1
Micrel, Inc.
MIC24046
2. Select RC1 to achieve the target crossover frequency
fXO of the overall voltage loop. This typically happens
where the power stage transfer function GCO(S) is
rolling off at -20dB/dec. The compensator transfer
function HC(S) is in the so-called mid-band gain region
where CC1 can be considered a DC-blocking short
circuit while CC2 can still be considered as an open
circuit, as calculated in Equation 20:
The MIC24046 uses a transconductance (GmEA =
1.5mA/V) error amplifier. Frequency compensation is
implemented with a Type-II network (RC1, CC1, and CC2)
connected from COMP to AGND. The compensator
transfer function consists of an integrator for zero DC
(voltage regulation error), a zero to boost the phase
margin of the overall loop gain around the crossover
frequency, and an additional pole that can be used to
cancel the output capacitor ESR zero, or to further
attenuate switching frequency ripple. In both cases, the
additional pole makes the regulation loop less susceptible
to switching frequency noise. The additional pole is
created by capacitor CC2. Equation 17 details the
compensator transfer function HC(S) (from OUTSNS to
COMP).
HC(S) = −
×
R1
1
× GmEA ×
R1 + R 2
S × (C C1 + C C2 )



The overall voltage loop gain TV(S) is the product of the
control-to-output and the compensator transfer functions:
TV (S) = GCO(S) × HC(S)
V
RL = O
IO
The value of the attenuation ratio R1/(R1 + R2) depends
on the output voltage selection, and can be retrieved as
illustrated in Table 5:
R1/(R1 + R2)
A
(A = 1 + R2/R1)
0.7V − 1.2V
1
1
1.5V − 1.8V
0.5
2
0.333
3
If the output capacitor is a polarized one, its ESR zero will
typically occur at low enough frequencies to cause the
loop gain to flatten out and not roll-off at a -20dB/decade
slope around or just after the crossover frequency fXO.
This causes undesirable scarce compensation design
robustness and switching noise susceptibility. The
compensator pole is then used to cancel the output
capacitor ESR zero, and achieve a well-behaved roll-off
of the loop gain above the crossover frequency.
1. Set the TV(S) loop gain crossover frequency fXO in the
range fS/20 to fS/10. Lower values of fXO allow a more
predictable and robust phase margin. Higher values
of fXO would involve additional considerations about
the current loop bandwidth in order to achieve a
robust phase margin. Taking a more conservative
approach is highly recommended.
fS
20
October 14, 2015
Eq. 22
The CC2 is intended for placing the compensator pole at
the frequency of the output capacitor ESR zero, and/or
achieve additional switching ripple/noise attenuation.
The compensation design process is as follows:
f XO ≈
C O × (ESR + R L )
R C1
4. Select capacitor CC2 to place the compensator pole at
the point where the frequency of the output capacitor
ESR is zero, or at ≥ 5 fXO, whichever is lower.
Table 5. Internal Feedback Divider Attenuation Values
2.5V(2.49V) − 3.3V
Eq. 21
Eq. 18
C C1 =
VO Range
Eq. 20
3. Select capacitor CC1 to place the compensator zero
at the load pole. The load pole moves around with
load variations, so to calculate the load pole use as a
load resistance RL the value determined by the
nominal output current IO of the application, as shown
in Equation 21 and Equation 22:
Eq. 17
(1 + S × R C1 × C C1 )

C × C C2
 1 + S × R C1 × C1
C
C1 + C C2

 R1 + R2  2π × C O × f XO
R C1 = 
⋅
 R1  GmEA ⋅ GmPS
If the output capacitors are only ceramic, then the ESR
zeroes frequencies could be very high. In many cases,
the frequencies could even be above the switching
frequency itself. Loop gain roll-off at −20dB/decade well
beyond the crossover frequency is ensured, but even in
this case, it is good practice to still make use of the
compensator pole to further attenuate switching noise,
while conserving phase margin at the crossover
Eq. 19
21
Revision 1.1
Micrel, Inc.
MIC24046
frequency. For example, setting the compensator pole at
5 fXO, will limit its associated phase loss at the crossover
frequency to about 11°. Placement at even higher
frequencies N × fXO (N > 5) will reduce phase loss even
further, at the expense of less noise/ripple attenuation at
the switching frequency. Some attenuation of the
switching frequency noise/ripple is achieved as long as N
× fXO < fS.
For polarized output capacitor, compensator pole
placement at the ESR zero frequency is achieved shown
in Equation 23:
C C2 =
1
R C1
1
−
C O × ESR C C1
Eq. 23
For ceramic output capacitor, compensator pole
placement at N × fXO (N ≥ 5, N × fXO < fS) is achieved as
detailed in Equation 24:
C C2 =
1
2π × R C1 × N × f XO −
1
C C1
Eq. 24
Output Voltage Soft-Start Rate
The MIC24046 features internal analog soft-start, such
that the output voltage can be smoothly increased to the
target regulation voltage. The soft-start rate given in the
Electrical Characteristics is referred to the error amplifier
reference, and therefore the effective soft-start rate value
seen at the output of the module has to be scaled
according to the internal feedback divider attenuation
values listed in Table 5. To calculate the effective output
voltage soft-start slew rate SS_SROUT based on the
particular output voltage setting and the reference softstart slew rate SS_SR, use the following formula:
SS _ SR OUT = A ⋅ SS _ SR
Eq. 25
Where:
The value of A (amplification, A =1 + R2/R1) is given in
the right column of Table 5.
October 14, 2015
22
Revision 1.1
Micrel, Inc.
MIC24046
Typical Application Schematic
Bill of Materials
Item
Part Number
C1
GRM31CR61E226ME15
C2, C7
GRM155R71E104KE14
C3, C4
C5, C6
Manufacturer
Description
Qty.
X5R, 22µF 25V 20%, Size 1206 Capacitor
1
Murata
X7R, 100nF 25V 10%, Size 0402 Capacitor
2
GRM31CR60J107ME39
Murata
X5R, 100uF 6.3V 20%, Size 1206 Capacitor
GRM155R61C225KE11
Murata
X5R, 2.2µF 16V 10%, Size 0402 Capacitor
2
C8
GRM1555C1H470JA01
Murata
C0G, 47pF 50V 5%, Size 0402 Capacitor
1
C9
GRM155R71E103KA01
Murata
X7R, 10nF 25V 10%, Size 0402 Capacitor
1
R1
RC0402-2551F
ANY
Chip, 2.55kΩ 1%, Size 0402 Resistor
1
R2
RC0402-103J
ANY
Chip, 10kΩ 5%, Size 0402 Resistor
1
SMT, 1.5µH, ISAT = 7.1A IRMS = 5.2A Inductor
1
Pin-Programmable, 4.5V − 19V, 5A Step-Down Converter
1
L1
U1
XAL4020-152ME
MIC24046YFL
Murata
(6)
Coilcraft
(7)
(8)
Micrel, Inc.
Notes:
6. Murata: www.murata.com.
7. Coilcraft: www.coilcraft.com.
8. Micrel, Inc.: www.micrel.com.
October 14, 2015
23
Revision 1.1
Micrel, Inc.
MIC24046
PCB Layout Recommendations
Top Layer
Layer 1
October 14, 2015
24
Revision 1.1
Micrel, Inc.
MIC24046
PCB Layout Recommendations (Continued)
Layer 2
Bottom Layer
October 14, 2015
25
Revision 1.1
Micrel, Inc.
MIC24046
Package Information and Recommended Land Pattern(9)
20-Pin 3mm × 3mm QFN (FL)
Note:
9. Package information is correct as of the publication date. For updates and most current information, go to www.micrel.com.
October 14, 2015
26
Revision 1.1
Micrel, Inc.
MIC24046
MICREL, INC. 2180 FORTUNE DRIVE SAN JOSE, CA 95131 USA
TEL +1 (408) 944-0800 FAX +1 (408) 474-1000 WEB http://www.micrel.com
Micrel, Inc. is a leading global manufacturer of IC solutions for the worldwide high performance linear and power, LAN, and timing & communications
markets. The Company’s products include advanced mixed-signal, analog & power semiconductors; high-performance communication, clock
management, MEMs-based clock oscillators & crystal-less clock generators, Ethernet switches, and physical layer transceiver ICs. Company
customers include leading manufacturers of enterprise, consumer, industrial, mobile, telecommunications, automotive, and computer products.
Corporation headquarters and state-of-the-art wafer fabrication facilities are located in San Jose, CA, with regional sales and support offices and
advanced technology design centers situated throughout the Americas, Europe, and Asia. Additionally, the Company maintains an extensive network
of distributors and reps worldwide.
Micrel makes no representations or warranties with respect to the accuracy or completeness of the information furnished in this datasheet. This
information is not intended as a warranty and Micrel does not assume responsibility for its use. Micrel reserves the right to change circuitry,
specifications and descriptions at any time without notice. No license, whether express, implied, arising by estoppel or otherwise, to any intellectual
property rights is granted by this document. Except as provided in Micrel’s terms and conditions of sale for such products, Micrel assumes no liability
whatsoever, and Micrel disclaims any express or implied warranty relating to the sale and/or use of Micrel products including liability or warranties
relating to fitness for a particular purpose, merchantability, or infringement of any patent, copyright, or other intellectual property right.
Micrel Products are not designed or authorized for use as components in life support appliances, devices or systems where malfunction of a product
can reasonably be expected to result in personal injury. Life support devices or systems are devices or systems that (a) are intended for surgical
implant into the body or (b) support or sustain life, and whose failure to perform can be reasonably expected to result in a significant injury to the user. A
Purchaser’s use or sale of Micrel Products for use in life support appliances, devices or systems is a Purchaser’s own risk and Purchaser agrees to fully
indemnify Micrel for any damages resulting from such use or sale.
© 2015 Micrel, Incorporated.
October 14, 2015
27
Revision 1.1