19-4815; Rev 2; 9/10
ৰۇ
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``````````````````````````````````` ᄂቶ
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ᄋࡉ4Bࡼၒ߲࢟ഗăNBY26152ᔫᏴ5/6Wᒗ39Wၒ
ྜྷ࢟ኹपᆍLjభࢯၒ߲࢟ኹपᆍᆐ1/7WᒗWJO ࡼ:1&Ljభᎅ
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ᆮኹĂ૦ࢻਫ਼Ă࢟၁ጲૺሿॅಢ࢟ᔇ።ă
♦ ࡉ4Bࡼೌኚၒ߲࢟ഗ
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ଐă
♦ ดᒙ281nΩ SET.PO ܟൈఎਈਜ਼216nΩ SET.PO
ࢅܟൈఎਈ
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ഉࡼ࢟Ꮞኔă
NBY26152ݧஂဏహମࡼࡍൈĂ4nn y 4nnĂ27୭
URGO.FQॖᓤLjᔫᏴ.51°Dᒗ,96°Dᆨࣞपᆍă
``````````````````````````````````` ።
ॊݚါ࢟ᇹᄻ
♦ ᑳৈᔫᆨࣞपᆍดۣߒ±2&ࡼၒ߲றࣞ
♦ 5/6Wᒗ39Wၒྜྷ࢟ኹपᆍ
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♦ 461lI{ৼࢾఎਈຫൈ
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♦ ᓆᒲ໐ਭഗۣઐ
♦ భྟ߈ܠࣅ
♦ ݧࢅFTSჿࠣၒ߲࢟ྏۣߒᆮࢾၒ߲
♦ ڔཝࣅྜྷᎾມᒙၒ߲
♦ ဧถၒྜྷਜ਼࢟Ꮞኙၒ߲
♦ 유ᑳࡼਭഗۣઐਜ਼ਭེۣઐ
♦ WEE MEP་ኹჄࢾ
♦ ஂဏహମĂᐐ༓ྲེࡼ4nn! y! 4nnॖᓤ
``````````````````````````````` ࢾ৪ቧᇦ
PART
MAX15041ETE+
TEMP RANGE
PINPACKAGE
TOP
MARK
-40°C to +85°C 16 TQFN-EP*
AGV
, ܭာᇄ)Qc*0९SpITܪᓰࡼॖᓤă
*FQ! >! ൡă
``````````````````````````` ࢜ቯᔫ࢟വ
༑း
INPUT
12V
Ꮎࢯஂ
૦ࢻਫ਼
IN
࢟၁
BST
OUTPUT
1.8V AT 3A
EN
yETMࢯᒜஊࢯ
MAX15041
ሿॅಢ࢟ᔇޘອ
LX
VDD
PGND
PGOOD
PGOOD
FB
SS
COMP
SGND
________________________________________________________________ Maxim Integrated Products
1
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षᆰNbyjnࡼᒦᆪᆀᐶǖdijob/nbyjn.jd/dpnă
NBY26152
``````````````````````````````````` গၤ
NBY26152
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ABSOLUTE MAXIMUM RATINGS
Continuous Power Dissipation (TA = +70°C)
16-Pin TQFN (derate 14.7mW/°C above +70°C)
Multilayer Board .........................................................1666mW
Package Thermal Resistance (Note 2)
θJA.................................................................................48°C/W
θJC ..................................................................................7°C/W
Operating Temperature Range ..........................-40°C to +85°C
Junction Temperature .....................................................+150°C
Storage Temperature Range ............................-65°C to +150°C
Lead Temperature (soldering, 10s) .................................+300°C
Soldering Temperature (reflow) .......................................+260°C
IN to SGND.............................................................-0.3V to +30V
EN to SGND .................................................-0.3V to (VIN + 0.3V)
LX to PGND ................................-0.3V to min (+30V, VIN + 0.3V)
LX to PGND .....................-1V to min (+30V, VIN + 0.3V) for 50ns
PGOOD to SGND .....................................................-0.3V to +6V
VDD to SGND............................................................-0.3V to +6V
COMP, FB, SS to SGND..............-0.3V to min (+6V, VDD + 0.3V)
BST to LX .................................................................-0.3V to +6V
BST to SGND .........................................................-0.3V to +36V
SGND to PGND ....................................................-0.3V to +0.3V
LX Current (Note 1) ....................................................-5A to +8A
Converter Output Short-Circuit Duration ...................Continuous
Note 1: LX has internal clamp diodes to PGND and IN. Applications that forward bias these diodes should take care not to exceed
the IC’s package power dissipation.
Note 2: Package thermal resistances were obtained using the method described in JEDEC specification JESD51-7, using a fourlayer board. For detailed information on package thermal considerations, refer to china.maxim-ic.com/thermal-tutorial.
Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional
operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to
absolute maximum rating conditions for extended periods may affect device reliability.
ELECTRICAL CHARACTERISTICS
(VIN = 12V, CVDD = 1μF, CIN = 22μF, TA = TJ = -40°C to +85°C, typical values are at TA = +25°C, unless otherwise noted.) (Note 3)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
STEP-DOWN CONVERTER
Input-Voltage Range
VIN
Quiescent Current
IIN
Shutdown Input Supply Current
4.5
28
V
2.1
4
mA
VEN = 0V, VDD regulated by internal
LDO
2
12
VEN = 0V, VIN = VDD = 5V
18
28
Not switching
μA
ENABLE INPUT
EN Shutdown Threshold Voltage
VEN_SHDN
EN Shutdown Voltage Hysteresis
VEN_HYST
EN Lockout Threshold Voltage
EN Input Current
VEN_LOCK
VEN rising
1.4
V
100
mV
VEN rising
1.7
1.95
2.15
IEN
VEN = 2.9V
2
5.3
9
μA
VPGOOD_TH
VFB rising
540
560
584
mV
100
mV
100
VEN_LOCK_HYST
V
mV
POWER-GOOD OUTPUT
PGOOD Threshold
PGOOD Threshold Hysteresis
VPGOOD_HYST
PGOOD Output Low Voltage
VPGOOD_OL
IPGOOD = 5mA, VFB = 0.5V
35
IPGOOD
VPGOOD = 5V, VFB = 0.7V
10
nA
1.6
mS
PGOOD Leakage Current
15
mV
ERROR AMPLIFIER
Error Amplifier
Transconductance
gMV
Error Amplifier Voltage Gain
AVEA
FB Set-Point Accuracy
VFB
FB Input Bias Current
IFB
2
90
600
606
dB
612
VFB = 0.5V
-100
+100
VFB = 0.7V
-100
+100
_______________________________________________________________________________________
mV
nA
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(VIN = 12V, CVDD = 1μF, CIN = 22μF, TA = TJ = -40°C to +85°C, typical values are at TA = +25°C, unless otherwise noted.) (Note 3)
PARAMETER
SYMBOL
CONDITIONS
SS Current
ISS
VSS = 0.45V, sourcing
SS Discharge Resistance
RSS
ISS = 10mA, sinking, VEN = 1.6V
MIN
TYP
MAX
UNITS
4.5
5
5.5
μA
SS Prebiased Mode Stop Voltage
Current Sense to COMP
Transconductance
GMOD
COMP Clamp Low
VFB = 0.7V
PWM Compensation Ramp Valley
6
Ω
0.65
V
9
S
0.68
V
830
mV
PWM CLOCK
Switching Frequency
fSW
Maximum Duty Cycle
D
315
Minimum Controllable On-Time
350
385
kHz
90
%
150
ns
INTERNAL LDO OUTPUT (VDD)
VDD Output Voltage
VDD
IVDD = 1mA to 25mA, VIN = 6.5V
VDD Short-Circuit Current
VIN = 6.5V
LDO Dropout Voltage
IVDD = 25mA, VDD drops by -2%
VDD Undervoltage Lockout
Threshold
VUVLO_TH
VDD Undervoltage Lockout
Hysteresis
VUVLO_HYST
4.75
5.1
30
80
VDD rising
5.5
V
mA
250
600
mV
4
4.25
V
150
mV
POWER SWITCH
LX On-Resistance
High-side switch, ILX = 1A
170
305
Low-side switch, ILX = 1A
105
175
6
7.2
High-Side Switch Source
Current-Limit Threshold
5
Low-Side Switch Sink
Current-Limit Threshold
LX Leakage Current
BST Leakage Current
-3
mΩ
A
A
VBST = 33V, VIN = VLX = 28V
10
VBST = 5V, VIN = 28V, VLX = 0V
10
VBST = 33V, VIN = VLX = 28V
10
nA
+155
°C
20
°C
nA
THERMAL SHUTDOWN
Thermal-Shutdown Threshold
Thermal-Shutdown Hysteresis
Rising
HICCUP PROTECTION
Blanking Time
16 x SoftStart Time
Note 3: Specifications are 100% production tested at TA = +25°C. Limits over the operating temperature range are guaranteed by
design and characterization.
_______________________________________________________________________________________
3
NBY26152
ELECTRICAL CHARACTERISTICS (continued)
````````````````````````````````````````````````````````````````````````` ࢜ቯᔫᄂቶ
(VIN = 12V, VOUT = 3.3V, CVDD = 1μF, CIN = 22μF, TA = +25°C, circuit of Figure 3 (see Table 1 for values), unless otherwise specified.)
EFFICIENCY vs. LOAD CURRENT
VOUT = 5.0V
VOUT = 3.3V
VOUT = 2.5V
65
VOUT = 1.8V
VOUT = 1.2V
60
55
50
0
0.5
1.0
1.5
2.0
2.5
75
VOUT = 3.3V
70
65
VOUT = 2.5V
60
VOUT = 1.8V
55
VOUT = 1.2V
50
3.0
0
-0.2
-0.4
-0.6
-0.8
-1.0
-1.2
0
0.5
1.0
1.5
2.0
2.5
3.0
0.5
0
1.0
2.0
2.5
LOAD CURRENT (A)
LOAD CURRENT (A)
LOAD-TRANSIENT WAVEFORMS
NORMALIZED OUTPUT VOLTAGE
vs. TEMPERATURE
NORMALIZED OUTPUT VOLTAGE
vs. TEMPERATURE
MAX15041 toc04
1.002
ILOAD
2A/div
VOUT
AC-COUPLED
200mV/div
VPGOOD
5V/div
NORMALIZED OUTPUT VOLTAGE
ILOAD = 0A
1.001
1.000
0.999
0.998
0.997
1.004
ILOAD = 2A
0.996
-40
1.002
1.000
0.998
0.996
0.994
-15
10
35
60
-15
-40
85
10
SWITCHING FREQUENCY
vs. INPUT VOLTAGE
FB SET POINT vs.TEMPERATURE
606
604
602
MAX15041 toc08
MAX15041 toc07
385
375
FREQUENCY (kHz)
FB SET POINT (mV)
608
365
355
345
TA = +85NC
335
TA = +25NC
TA = -40NC
325
600
-40
-15
10
35
TEMPERATURE (NC)
60
35
TEMPERATURE (NC)
TEMPERATURE (NC)
610
85
3.0
0.992
0.995
200μs/div
4
1.5
LOAD CURRENT (A)
MAX15041 toc06
70
80
NORMALIZED OUTPUT VOLTAGE
75
85
MAX15041 toc05
80
EFFICIENCY (%)
85
MAX15041 toc03
90
OUTPUT-VOLTAGE REGULATION (%)
90
VIN = 5V
95
0.2
MAX15041 toc02
100
MAX15041 toc01
VIN = 12V
95
OUTPUT-VOLTAGE REGULATION
vs. LOAD CURRENT
EFFICIENCY vs. LOAD CURRENT
100
EFFICIENCY (%)
NBY26152
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315
0
5
10
15
20
INPUT VOLTAGE (V)
_______________________________________________________________________________________
25
60
85
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13
12
8
7
6
5
4
3
2
11
4.0
MAX15041 toc11
9
SHUTDOWN CURRENT (FA)
14
10
MAX15041 toc10
L = 4.7FH
ILOAD = 0A
SHUTDOWN CURRENT (FA)
MAX15041 toc09
INPUT SUPPLY CURRENT (mA)
16
15
SHUTDOWN CURRENT
vs. TEMPERATURE
SHUTDOWN CURRENT
vs. INPUT VOLTAGE
INPUT SUPPLY CURRENT
vs. INPUT VOLTAGE
3.5
3.0
2.5
2.0
1.5
1
1.0
0
10
0
5
10
15
20
0
25
5
10
15
20
25
-40
-15
SHUTDOWN WAVEFORMS
10
35
85
OUTPUT SHORT-CIRCUIT WAVEFORMS
MAX15041 toc12
MAX15041 toc13
VEN
5V/div
VOUT
2V/div
IIN
5A/div
VOUT
2V/div
IL
5A/div
IL
2A/div
VPGOOD
5V/div
100μs/div
VSS
2V/div
10ms/div
SOFT-START WAVEFORMS
SWITCHING WAVEFORMS
MAX15041 toc15
MAX15041 toc14
VEN
5V/div
VLX
10V/div
VOUT
2V/div
IL
2A/div
IL
2A/div
VOUT
AC-COUPLED
50mV/div
1μs/div
60
TEMPERATURE (NC)
INPUT VOLTAGE (V)
INPUT VOLTAGE (V)
VPGOOD
5V/div
400μs/div
_______________________________________________________________________________________
5
NBY26152
```````````````````````````````````````````````````````````````````` ࢜ቯᔫᄂቶ)ኚ*
(VIN = 12V, VOUT = 3.3V, CVDD = 1μF, CIN = 22μF, TA = +25°C, circuit of Figure 3 (see Table 1 for values), unless otherwise specified.)
```````````````````````````````````````````````````````````````````` ࢜ቯᔫᄂቶ)ኚ*
(VIN = 12V, VOUT = 3.3V, CVDD = 1μF, CIN = 22μF, TA = +25°C, circuit of Figure 3 (see Table 1 for values), unless otherwise specified.)
SOFT-START TIME
vs. CAPACITANCE
STARTUP INTO PREBIASED OUTPUT
MAX15041 toc17
MAX15041 toc16
1000
SOFT-START TIME (ms)
VEN
5V/div
100
VOUT
2V/div
10
IL
2A/div
1
IOUT
2A/div
0.1
1
10
100
400μs/div
1000
CSS (nF)
MAX15041 toc18
3.2
VEN
5V/div
VOUT
2V/div
IL
5A/div
IOUT
5A/div
MAX15041 toc19
MAXIMUM LOAD CURRENT
vs. AMBIENT TEMPERATURE
STARTUP INTO PREBIASED OUTPUT
MAXIMUM LOAD CURRENT (A)
NBY26152
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VIN = 5V
TJ P +150NC
3.0
2.8
VOUT = 3.3V
2.6
VOUT = 2.5V
2.4
VOUT = 1.8V
VOUT = 1.2V
2.2
2.0
400μs/div
5
15
25
35
45
55
65
75
AMBIENT TEMPERATURE (NC)
6
_______________________________________________________________________________________
85
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MAXIMUM LOAD CURRENT (A)
VIN = 12V
TJ P +150NC
3.0
3.2
MAX15041 toc20
2.8
VOUT = 3.3V
VOUT = 2.5V
2.6
VOUT = 1.8V
2.4
VOUT = 1.2V
VIN = 28V
TJ P +150NC
3.0
2.8
VOUT = 1.2V
2.6
VOUT = 3.3V
VOUT = 2.5V
2.4
VOUT = 1.8V
2.2
2.2
2.0
2.0
15
5
25
35
45
55
65
75
15
5
85
DEVICE POWER DISSIPATION
vs. LOAD CURRENT
VIN = 12V
45
55
65
75
85
3.0
VOUT = 3.3V
VIN = 5V
2.5
POWER DISSIPATION (W)
POWER DISSIPATION (W)
2.5
VOUT = 2.5V
VOUT = 1.8V
1.5
35
DEVICE POWER DISSIPATION
vs. LOAD CURRENT
MAX15041 toc22
3.0
2.0
25
AMBIENT TEMPERATURE (NC)
AMBIENT TEMPERATURE (NC)
VOUT = 1.2V
1.0
0.5
MAX15041 toc23
MAXIMUM LOAD CURRENT (A)
3.2
MAX15041 toc21
MAXIMUM LOAD CURRENT
vs. AMBIENT TEMPERATURE
MAXIMUM LOAD CURRENT
vs. AMBIENT TEMPERATURE
VOUT = 3.3V
VOUT = 2.5V
2.0
VOUT = 1.8V
VOUT = 1.2V
1.5
1.0
0.5
0
0
0.5
1.0
1.5
2.0
LOAD CURRENT (A)
2.5
3.0
0
0
0.5
1.0
1.5
2.0
2.5
3.0
LOAD CURRENT (A)
_______________________________________________________________________________________
7
NBY26152
```````````````````````````````````````````````````````````````````` ࢜ቯᔫᄂቶ)ኚ*
(VIN = 12V, VOUT = 3.3V, CVDD = 1μF, CIN = 22μF, TA = +25°C, circuit of Figure 3 (see Table 1 for values), unless otherwise specified.)
```````````````````````````````````````````````````````````````````````````` ୭ᒙ
LX
LX
LX
BST
TOP VIEW
12
11
10
9
PGND 13
PGND 14
MAX15041
IN 15
*EP
1
2
3
4
EN
COMP
+
PGOOD
IN 16
VDD
NBY26152
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8
I.C.
7
SGND
6
SS
5
FB
TQFN
*EXPOSED PAD, CONNECT TO SGND.
``````````````````````````````````````````````````````````````````````````` ୭ႁී
8
୭
߂
ถ
1
VDD
2
PGOOD
3
EN
4
COMP
5
FB
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ၒ߲࢟ኹă
6
SS
ྟࣅၒྜྷăᏴTTᎧTHOEᒄମೌጙৈ࢟ྏLjᒙྟࣅဟମ)༿ݬᒙྟࣅဟମݝॊ*ă
7
SGND
8
I.C.
ดೌݝLjೌᒗTHOEă
9
BST
ܟNPTGFUདࣅ࢟Ꮞăಽጙৈ21oG࢟ྏCTUവᒗMYLjᏴWEE ᒗCTUᒄମೌጙৈᅪݝऔ
)༿ݬऔኡᐋݝॊ*ă
10, 11, 12
LX
13, 14
PGND
15, 16
IN
ၒྜྷ࢟Ꮞăၒྜྷ࢟Ꮞपᆍᆐ5/6Wᒗ39WLjಽጙৈᒗ33μGࡼჿࠣ࢟ྏവࡵQHOEă
—
EP
ൡăᅪೌݝᒗTHOELjൡࡵೌኚࡼࡍෂ૩१ᄵຳෂLjጲࡻᔢଛྲེቶถă
ดݝMEP! 6Wၒ߲ă᎖ดݝෝผดਖ਼࢟വ࢟ࡼ࢟ᏎၒྜྷLjಽጙৈᒗ2μGࡼჿࠣ࢟ྏവᒗTHOELj
༿ݬᅄ4ă
࢟Ꮞኙఎധၒ߲ăྙਫGCࢅ᎖656nWLjQHPPEᒙᆐࢅ࢟ຳă
ဧถၒྜྷăFOᆐၫᔊၒྜྷLjభఎĂਈஂࢯܕăFOདࣅᒗ࢟ຳLjఎࢯஂăೌࡵJOဟLj
ࢯஂဪᒫۣߒᔫă
࢟ኹᇙތहࡍၒ߲ăᏴDPNQਜ਼THOEᒄମೌܘገࡼޡݗᆀă
ෝผLjᏴణதၒྜྷവ࢟ྏऩૄ࢛࣡ೌᒗQHOEຳෂă
࢟ঢೌ࣡ăMY୭ೌࡵ࢟ঢࡼఎਈݾăࡩJDࠀ᎖ਈࣥෝါĂེਈࣥෝါWEE ࢅ᎖VWMPඡሢဟLj
MYᆐᔜზă
ൈLjᏴణதၒྜྷവ࢟ྏऩૄ࢛࣡ೌᒗTHOE! QDC१ᄵຳෂă
_______________________________________________________________________________________
ࢅ߅۾Ă4BĂ5/6Wᒗ39WၒྜྷĂ461lI{! QXN
ଢ଼ኹቯED.EDࢯஂLjดᒙఎਈ
ENABLE CONTROL
AND THERMAL
SHUTDOWN
EN
5V LDO
VDD
UVLO
COMPARATOR
4V
MAX15041
VDD
BIAS
GENERATOR
BST
CURRENT-SENSE/CURRENT-LIMIT
AMPLIFIER
IN
LX
VOLTAGE
REFERENCE
N
CONTROL
LOGIC AND
SINK LIMIT
0.65V
LX
VDD
STRONG PREBIAS
COMPARATOR
5μA
N
PWM
COMPARATOR
0.606V
PGND
SS
FB
ERROR
AMPLIFIER
Σ
OSCILLATOR
COMP
PGOOD
SGND
N
0.560V RISING,
0.545V FALLING
POWER-GOOD
COMPARATOR
_______________________________________________________________________________________
9
NBY26152
```````````````````````````````````````````````````````````````````````````` ଼છౖᅄ
NBY26152
ࢅ߅۾Ă4BĂ5/6Wᒗ39WၒྜྷĂ461lI{! QXN
ଢ଼ኹቯED.EDࢯஂLjดᒙఎਈ
``````````````````````````````` ሮᇼႁී
3* ࡉࡵܟNPTGFU࢟ഗሢᒜă
NBY26152ᆐĂख़ᒋ࢟ഗෝါĂଢ଼ኹቯED.EDᓞધLj
ด߅ૹݝ)ܟ281nΩLj࢜ቯᒋ*ਜ਼ࢅ)ܟ216nΩLj࢜ቯᒋ*
ൈఎਈăᄰਭᅪ࢟ݝᔜॊኹభጲၒ߲࢟ኹᒙᏴ
1/717W ᒗ 1/: y W JO ᒄମLj݀భᄋࡉ 4B ࡼঌᏲ࢟ഗă
5/6Wᒗ39Wၒྜྷ࢟ኹपᆍဧকୈభಯሯ᎖ॊݚါ࢟
ᇹᄻĂ܊࢟۾ฎጲૺᎾᆮኹଐă
4* ࡉࡵ:1&ࡼᔢࡍᐴహ܈ă
NBY26152ᎌQXN఼ᒜLjᔫᏴ461lI{ดࢾৼݝఎ
ਈຫൈLjᎌ:1&ࡼᔢࡍᐴహ܈ăQXN࢟ഗෝါ఼ᒜᑽ
ߒཝჿࠣ࢟ྏଐăNBY26152ดᒙᐐፄోࡴᇙތहࡍ
Lj࢟ഗෝါ఼ᒜଦ৩଼છ೫ޡݗଐ݀ཀྵۣᓆᒲ໐ሢ
ഗLj݀భႥሰ።ၒྜྷ࢟Ꮞਜ਼ঌᏲၾܤăࢅSET.PO ࡼຢ
ดNPTGFUఎਈถ৫ཀྵۣᒮᏲဟᄋൈLjଢ଼ࢅ೫࣪
ည࢟ঢࡼገཇጲૺ࣪࢟വݚۇࡼැঢቶă
NBY26152થᎌེਈࣥਜ਼ਭഗۣઐ)ܟᏎ߲࢟ഗĂࢅ
ܟᇢྜྷ࢟ഗ*Ăࡒ་ኹჄࢾࡼดݝ6W MEPăᅪݝభࢯஂࡼ
࢟ኹྟࣅถᓆ୍ᐐࡍၒ߲࢟ኹLjିቃ೫፻࢟ഗă
ࣖೂࡼဧถ఼ᒜਜ਼࢟Ꮞኙቧభဣሚഉࡼ࢟Ꮞኔ
ଐăNBY26152ถ৫ᏴࣅઁྜྷᎾມᒙၒ߲LjকᎾᒙ
ၒ߲భࢅ᎖᎖ᒙ࢟ኹă
఼ᒜถ—QXN൝
NBY26152ᔫᏴ461lI{ৼࢾఎਈຫൈăFOᆐ࢟ຳဟLj
ᏴளਭࡼೂဟମઁLjࡩWTT ᏗਭGC࢟ኹఎྟࣅ
ဟLjQXNఎဪᔫă
Ᏼఎဪᔫࡼጙৈဟᒩᒲ໐LjܟNPTGFUࡴᄰăखည
ྙሆ༽ౚဟLjܟNPTGFUਈࣥǖ
2* DPNQ࢟ኹᏗਭด࢟ݝഗෝါဍ݆ተLjক݆ተᆐޡݗ
ቓຸᎧ࢟ঢ࢟ഗॊഗ)ଶഗ࢟വ*ࡻࡵࡼ࢟ഗෝါဍ݆
ተᒄਜ਼ă
10
ႲઁLjࢅܟNPTGFUࡴᄰLjᏴဟᒩᒲ໐உၦဟࢅܟNPTGFU
ਈࣥă
ࣅྜྷᎾມᒙၒ߲
NBY26152భጲᏴ࣪ݙၒ߲࢟ྏह࢟ࡼ༽ౚሆڔཝྟ
ࣅྜྷᎾມᒙၒ߲ăࣅྜྷᎾມᒙᓨზဟLjࢅܟਜ਼
ܟNPTGFUۣߒਈࣥLjܜ࣪Ꮎມᒙၒ߲ह࢟ăᒑᎌࡩ
TT࢟ኹᏗਭGC࢟ኹဟݣࣅQXNᔫăNBY26152થభ
ጲྟࣅઁࡉࡵ᎖PVU߂ܪᒙࡼၒ߲Ꮎᒙ࢟ኹăᑚ
ᒬ༽ౚሆLjࡩTT࢟ኹࡉࡵ1/76W )࢜ቯᒋ*ဟ༓ᒜQXNᔫă
ᏴᎾມᒙၒ߲ࢅ᎖᎖ PVU ߂ܪᒙ࢟ኹࡼ༽ౚሆLj
ྙਫࢅܟNPTGFUᇢ࢟ഗࡉࡵᇢ࢟ഗሢᒜ).4BLj࢜ቯᒋ*Lj
ᐌᏴဟᒩᒲ໐உၦᒄ༄ਈࣥࢅܟNPTGFULj݀ࡴᄰܟ
NPTGFULjᒇࡵखညሆ༽ተᒄጙǖ
2* ܟNPTGFUᏎ߲࢟ഗࡉࡵଢ଼ࢅઁࡼܟNPTGFU࢟ഗ
ඡሢ)1/86BLj࢜ቯᒋ*ăᑚᒬ༽ౚሆLjᏴဟᒩᒲ໐ထ
ဟମดܟNPTGFUਈࣥă
3* ဟᒩᒲ໐உၦă
ဧถၒྜྷਜ਼࢟Ꮞኙၒ߲
NBY26152ᎌࣖೂࡼୈဧถ఼ᒜਜ਼࢟ᏎኙቧLjభ
ဣሚഉࡼ࢟Ꮞኔଐăဧถၒྜྷ)FO*ᎌ2/:6W! )࢜
ቯᒋ*ࡼඡሢLj᎖఼ᒜࢯஂă࣪FOဗଝጙৈ᎖ඡሢ
ᒋࡼ࢟ኹ૾భဧถࢯஂLjFOೌࡵJOဧဪᒫۣ
ߒᔫă࢟Ꮞኙ)QHPPE*ᆐധఎവၒ߲LjࡩWGC ᎖
671nW )࢜ቯᒋ*ဟࠀ᎖ᑵޟኙᓨზ)ᆐᔜზ*ǗࡩWGC
ࢅ᎖656nW )࢜ቯᒋ*ဟ߿ۻखᆐࢅ࢟ຳă
ࡩFO࢟ኹ᎖2/5W )࢜ቯᒋ*༦ࢅ᎖2/:6W )࢜ቯᒋ*ဟLjࡍ
ݝॊด࢟ݝവਈܕLjᒑᎌดࢯ࠰ݝᎾᆮኹࢯஂ)۞౪FO
றࣞ୷܈*ۣߒᔫă
______________________________________________________________________________________
ࢅ߅۾Ă4BĂ5/6Wᒗ39WၒྜྷĂ461lI{! QXN
ଢ଼ኹቯED.EDࢯஂLjดᒙఎਈ
NBY26152ݧྟࣅဧࢯஂၒ߲࢟ኹદൻဍLjጲି
ቃࣅဟࡼၒྜྷ፻࢟ഗăᏴTTਜ਼THOEᒄମೌጙৈ࢟
ྏLj᎖ᒙࣅဟମ)ਈ᎖࢟ྏኡᐋࡼሮᇼቧᇦ༿ݬఠ
ᒙྟࣅဟମݝॊ*ă
ดݝMEP! )WEE*
NBY26152ࡒᎌดݝ6/2W )࢜ቯᒋ* MEPăWEE ᆐᅪޡݗݝ
࣡Ljೌጙৈᔢቃ2μGࡼࢅFTSჿࠣ࢟ྏăWEE ࢟ኹᆐࢅ
ܟNPTGFUདࣅጲૺด఼ݝᒜ൝࢟വ࢟ăࡩၒྜྷ࢟
ኹ)JO*ࢅ᎖5/6WဟLjWEE ܈JOࢅ61nW )࢜ቯᒋ*ăWEE ၒ߲
࢟ഗሢᒜᏴ91nB )࢜ቯᒋ*LjࡩWEE ࢅ᎖4/96W )࢜ቯᒋ*ဟLj
VWMP࢟വணᒏఎਈᔫă
ᇙތहࡍ
ᐐፄᇙތहࡍ࣪࢟ኹनౣણവᄋறමࢯஂăᏴ
DPNQਜ਼THOEᒄମೌܘገࡼޡݗᆀ)༿ݬఠޡݗଐ
ݝॊ*ăᇙތहࡍోࡴᆐ2/7nT )࢜ቯᒋ*LjDPNQሆሢὥ
ᆡᒙᆐ1/79W )࢜ቯᒋ*Ljੑࢅ᎖QXNဍࡼޡݗ৸ᒋă
ࡩঌᏲਜ਼ၒྜྷ࢟Ꮞၾܤဟᎌᓐ᎖DPNQႥऩૄᑵཀྵࡼ
ᒙ࢛ă
QXN୷܈
QXN୷܈DPNQ࢟ኹᎧᏎᔈ࢟ഗࡼဍ݆ተ)MY࢟ഗ
ᎧDPNQ࢟ኹࡴోࡼ܈ᒋᆐ:B0WLj࢜ቯᒋ*ቲ୷܈ăᆐ
೫ܜᏴᐴహ܈ᆐ61&ৎဟᎅ᎖ቕ݆ᑩࡴᒘݙᆮ
ࢾLjኍ࣪Ꮞᔈ࢟ഗࡼဍ݆ተᐐଝቓຸޡݗăޡݗቓൈ
)1/56W! y! 461lI{*ࢀ᎖ᔢތᔫᄟୈሆ)4BঌᏲĂ࢟ഗᆬ
݆41&Ăᔫ᎖:1&ᔢࡍᐴహ࢟*܈ঢ࢟ഗሆଢ଼ቓൈࡼጙۍă
ޡݗቓຸ৸ᒋᒙᆐ1/94W )࢜ቯᒋ*ă
ਭഗۣઐጲૺࡌᡅෝါ
ࠥᅪLjથᏴৼࢾဟମ)ΔU1 > 81otLj࢜ቯᒋ*ด࣪TT࢟ྏDTT
ቲह࢟ăྙਫਭഗᓨზ྆ࡀᏴLjTT౯ᒗ1/717Wጲ
ሆLj݀ఎࡌᡅෝါă
ࡌᡅෝါሆLjܟਜ਼ࢅܟNPTGFUਈࣥLjDPNQ౯ᒗࢅ
࢟ຳࡼဟମࢀ᎖27۶ࡼྟࣅ߂ܪဟମ)ືဟମ*ăጲ
6μB )࢜ቯᒋ*࢟ഗTT࠭1ߠ࢟ᒗ1/717WLjઁጲ444oB
)࢜ቯᒋ*࢟ഗદൻह࢟ᒗ1WLjᎅ఼ࠥᒜဟମăளਭື
ဟମઁLjୈఎဪޞ၂ᒮቤࣅăྙਫਭഗ৺ᑇጯள
ஊ߹LjୈૂআᑵޟᔫLj॥ᐌLj߿खቤࡼࡌᡅෝါ
)༿ݬఠ࢜ቯᔫᄂቶᒦࡼPvuqvu Tipsu.Djsdvju Xbwfgpsnt*ă
ེਈۣࣥઐ
NBY26152ดᒙᆨࣞࠅঢLjሢᒜୈࡼᔐ݀Ᏼޠ໐
ਭེ৺ᑇᓨზሆۣઐୈăࡩበᆨࣞިਭ,266°D )࢜ቯ
ᒋ*ဟLjᆨࣞࠅঢਈࣥୈLjਈܕED.EDᓞધਜ਼MEP
ࢯஂLjဧበದསăࡩበᆨࣞሆଢ଼31°D )࢜ቯᒋ*ઁLj
ୈᄰਭྟࣅਭ߈ᒮቤఎă
``````````````````````````````` ።ቧᇦ
ᒙၒ߲࢟ኹ
ᏴPVUĂGCĂTHOEᒄମೌ࢟ᔜॊኹ)S2 ਜ਼S3Ljྙᅄ2
ਜ਼ᅄ4Ⴥာ*᎖ᒙED.EDᓞધࡼၒ߲࢟ኹăኡᐋS 2
ਜ਼S3 ဧGCၒྜྷມᒙ࢟ഗྜྷࡼᒇഗᇙ્ݙތ፬ሰၒ߲࢟
ኹறࣞăݧࢅᔜᒋ࢟ᔜᎌᓐ᎖ଢ଼ࢅᒇഗᇙތLjࡣ࢟ᔜ
ॊኹࡼᑳᄏᐐࡍăS 3 ࢜ቯᒋᄰޟᆐ21lΩLj6lΩᒗ
61lΩᒄମࡼ࢟ᔜᒋభ၊ăጙࡡኡࢾS3LjሆါଐႯ
S2ǖ
⎛V
⎞
R1 = R2 × ⎜ OUT − 1⎟
⎝ VFB
⎠
नౣඡሢ࢟ኹWGC > 1/717W )࢜ቯᒋ*ă
ࡩᓞધၒ߲വୈਭᏲဟLjܟNPTGFU࢟ഗሢᒜ
)7BLj࢜ቯᒋ*ਈࣥܟNPTGFU݀ࡴᄰࢅܟNPTGFUă
______________________________________________________________________________________
11
NBY26152
భྟ߈ܠࣅ)TT*
NBY26152
ࢅ߅۾Ă4BĂ5/6Wᒗ39WၒྜྷĂ461lI{! QXN
ଢ଼ኹቯED.EDࢯஂLjดᒙఎਈ
࢟ঢኡᐋ
ࡍ࢟ঢᎌᓐ᎖ିቃ࢟ঢᆬ݆࢟ഗLj࠭ऎଢ଼ࢅၒ߲ᆬ݆࢟
ኹăࡣဵLjࡍ࢟ঢᎌ୷ࡍࡼᇕಯߛࡁLjऎ༦ࠈೊ࢟ᔜ
)EDS*୷ࡍĂऄࢾۥਜ਼࢟ഗ୷ࢅăᄰޟLjኡᐋ࢟ঢᒋဧ࢟
ഗᆬ݆ࢀ᎖41&ࡼঌᏲ࢟ഗLjᄰਭሆါଐႯ࢟ঢǖ
⎛ V
⎞
VOUT
L=
× 1 − OUT ⎟
fSW × ΔIL ⎜⎝
VIN ⎠
ᒦLjgTX ᆐดݝ461lI{ৼࢾఎਈຫൈLjΔJM ᆐ࢟ঢᆬ݆࢟
ഗৰଐᒋ)ᄰޟᒙᆐ1/4 y JMPBE*ăᅪLjख़ᒋ࢟ঢ࢟ഗ
JM`QL ܘኍဪᒫࢅ᎖ܟNPTGFU࢟ഗሢࡼᔢቃᒋJITDM`NJO
)6BLj࢜ቯᒋ*ਜ਼࢟ঢࡼऄࢾۥਜ਼࢟ഗJM`TBUăཀྵۣ൸ᔗሆ
ෂࡼਈᇹါǖ
1
IL _ PK = ILOAD + × ΔIL < min(IHSCL _ MIN ,IL _ SAT )
2
औኡᐋ
NBY26152ኊገጙৈᅪݝᔈऔLjऔೌᏴWEE
ਜ਼CTUᒄମăऔࡼनሶ࢟ኹऄࢾᒋܘኍ᎖ᓞધࡼ
ၒྜྷ࢟ኹLjऄࢾ࢟ഗᒗᆐ311nBăᄰޟLjক።ᒦኊገ
ݧႥఎਈऔቆᄂऔLjࡣ଼ࡼࢅ߅۾
औ)2O5118*ጐభ൸ᔗገཇă
ၒྜྷ࢟ྏኡᐋ
࣪᎖ଢ଼ኹᓞધLjၒྜྷ࢟ྏDJO ᎌᓐ᎖ۣߒᒇഗၒྜྷ࢟ኹ
ࡼᆮࢾLjᇄ൙ၒྜྷୣഗ࢟ഗဵ॥ೌኚăᆐଢ଼ࢅᎅ᎖FTS
ࡼ࢟ኹᆬ݆LjࢅFTSࡼ࢟ྏᆐᔢଛኡᐋă
DJO ᎅሆါଐႯǖ
CIN =
ILOAD
V
× OUT
fSW × ΔVIN _ RIPPLE
VIN
ၒ߲࢟ྏኡᐋ
ᅎୀဧࢅFTS࢟ྏጲିቃFTSࡼ࢟ኹᆬ݆ăᔐࡼၒ
߲࢟ኹᆬ݆ख़ख़ᒋᎅሆါৰႯǖ
ΔVOUT =
12
⎞
⎛ V
⎞ ⎛
VOUT
1
× 1 − OUT ⎟ × ⎜ RESR _ COUT +
8 × fSW × COUT ⎟⎠
fSW × L ⎜⎝
VIN ⎠ ⎝
࣪᎖ჿࠣ࢟ྏLjభFTSࡼ፬ሰǖ
RESR _ COUT <<
1
8 × fSW × COUT
࣪᎖ᶉ࢟ྏ࢟ஊ࢟ྏLjFTSࡼ፬ሰᐴᓍገᆡǖ
1
RESR _ COUT >>
8 × fSW × COUT
ޡݗଐ
NBY26152ݧৼࢾຫൈĂख़ᒋ࢟ഗ఼ᒜෝါଦ৩Ljጵ᎖
݀ޡݗᎌႥၾზሰ።ăᓆᒲ໐ପ࢟ހঢख़ᒋ࢟ഗ݀
ᎧDPNQ࢟ኹቲ࢟)୷܈ኹᇙތहࡍၒ߲*ăো࢟ঢ
ख़ᒋ࢟ഗ࣪ࢯஂࡼᐴహ܈ቲࢯᑳăᓆᒲ໐఼ᒜ࢟ঢ
࢟ഗಢ႒᎖ጙৈ၊఼࢟ഗᏎăፐࠥLj࢟ঢࡼ࢛ຫൈᏐ
Ꮠࡍ᎖ࢯஂࡼᐐፄࡒă
ᏴDPNQਜ਼THOEᒄମᄗଝ଼ࡼࠈೊ࢟ྏਜ਼࢟ᔜLjۣᑺ
ᇹᄻᆮࢾቶăᑚᒬ࢛.ഃ࢛ࡼৢᄴᔫ൸ᔗܕણᇹᄻࡼ
ሰ።ገཇă
ࢯࡼ۾ᑳણവᎅ࢟Ꮞࢯஂ)ᎅࢯஂࡼ൴ࢯᒜĂ
ቓຸޡݗĂ఼ᒜ࢟വĂNPTGFUਜ਼࢟ঢ৩߅*Ă࢟ྏၒ߲
݆ਜ਼ঌᏲĂၒ߲नౣॊኹĂ࢟ኹણവᇙތहࡍ
ጲૺᎧሤਈࡼ࢟ޡݗവ৩߅Ljᅄ2߲೫࢟വႁීă
ഗਭ࢟ঢࡼຳ࢟ഗᎅሆါଐႯǖ
IL = GMOD × VCOMP
ᒦLjJM ᆐ࢟ঢࡼຳ࢟ഗLjHNPE ᆐ࢟Ꮞࢯஂࡼోࡴă
࣪᎖ଢ଼ኹᓞધǖ
VOUT = R LOAD × IL
ᒦLjSMPBE ᆐࢀঌᏲ࢟ᔜᒋăஉၤೝৈါLj࢟
Ꮞࢯஂࡼࠅၒၫ)WPVU ᎧWDPNQ ࡼܭ*܈ာᆐǖ
VOUT
R
×I
= LOAD L = RLOAD × GMOD
VCOMP
⎛ IL ⎞
⎜⎝ G
⎟
MOD ⎠
______________________________________________________________________________________
ࢅ߅۾Ă4BĂ5/6Wᒗ39WၒྜྷĂ461lI{! QXN
ଢ଼ኹቯED.EDࢯஂLjดᒙఎਈ
COMPENSATION
RAMP
VOUT
Σ
FB
R1
NBY26152
POWER MODULATOR
ERROR AMPLIFIER
FEEDBACK
DIVIDER
OUTPUT FILTER
AND LOAD
VIN
gMC
COMP
QHS
VOUT
L0
CONTROL
LOGIC
R2
RC
ROUT
gMV
PWM
COMPARATOR
*CCC
QLS
DCR
IL
ESR
RLOAD
COUT
CC
VCOMP
GMOD
VOUT
IL
ROUT = AVEA/gMV
*CCC IS OPTIONAL.
REF
NOTE: THE GMOD STAGE SHOWN ABOVE MODELS THE AVERAGE CURRENT OF
THE INDUCTOR INJECTED INTO THE OUTPUT LOAD. THIS REPRESENTS A
SIMPLIFICATION FOR THE POWER MODULATOR STAGE DRAWN ABOVE.
ᅄ2/! ख़ᒋ࢟ഗෝါࢯஂࡼࠅၒၫෝቯ
ࢾፃ೫࢟ᏎࢯஂࡼࠅၒၫᐐፄઁLjᇹᄻણവᔐᐐፄ
ྙሆါჅာ)ᅄ2Ⴥာ*ǖ
α=
ROUT × ( sCCRC + 1)
⎡⎣s ( CC + CCC ) (RC + ROUT ) + 1⎤⎦ × ⎡⎣s ( CC || CCC )(RC || ROUT ) + 1⎤⎦
β = GMOD × RLOAD ×
ᐐፄ
(sCOUTESR + 1)
⎡⎣sCOUT (ESR + RLOAD ) + 1⎤⎦
R2
A
× VEA × α × β
=
R1 + R2 ROUT
ᒦLjSPVU ᆐᇙތहࡍᒇഗᐐፄBWFB ߹ጲᇙތहࡍ
ోࡴhNW ࡼǗSPVU ᏐᏐࡍ᎖SDĂDD ᏐᏐࡍ᎖DDDă
ါభখቖᆐǖ
ᐐፄ =
(sCCRC + 1)
VFB
A VEA ×
VOUT
⎡
⎛ A VEA ⎞ ⎤
+ 1⎥ × ( sCCCRC + 1)
⎢sCC ⎜
⎝ gMV ⎟⎠ ⎦
⎣
× GMODRLOAD ×
ણവࠅၒၫᐐፄࡼᓍ࢛ਜ਼ഃ࢛ྙሆჅာǖ
gMV
1
fP2 =
2π × COUT (ESR + RLOAD )
2π × 10 AVEA [dB] / 20 × CC
1
1
fP3 =
fZ1 =
2π × CCCRC
2π × CCRC
fP1 =
fZ2 =
1
2π × COUTESR
࢛.ഃ࢛ၿኔᆐǖ
fP1 < fP2 < fZ1 < fZ2 ≤ fP3
ᓖፀǖᏴᒮᏲဟLjgQ3 ᎌభถި༄᎖g[2ă
୍ᇹᄻࡼܕણሰ።ᅄ)۞౪ᓍ࢛ਜ਼ഃ࢛ᆡᒙ*ྙᅄ 3
Ⴥာă
(sCOUTESR + 1)
⎡⎣sCOUT (ESR + RLOAD ) + 1⎤⎦
______________________________________________________________________________________
13
NBY26152
ࢅ߅۾Ă4BĂ5/6Wᒗ39WၒྜྷĂ461lI{! QXN
ଢ଼ኹቯED.EDࢯஂLjดᒙఎਈ
GAIN
1ST ASYMPTOTE
VFB x VOUT -1 x 10AVEA[dB]/20 x GMOD x RLOAD
2ND ASYMPTOTE
VFB x VOUT -1 x gMV x (CC)-1 x GMOD x RLOAD
3RD ASYMPTOTE
VFB x VOUT -1 x gMV x (CC)-1 x GMOD x RLOAD x (COUT(ESR + RLOAD))-1
4TH ASYMPTOTE
VFB x VOUT -1 x gMV x RC x GMOD x RLOAD x (COUT(ESR + RLOAD))-1
3RD POLE
(CCCRC)-1
2ND ZERO
(COUTESR)-1
UNITY
1ST POLE
gMV x (10AVEA[dB]/20 CC)-1
RAD/S
1ST ZERO
(CCRC)-1
CO
2ND POLE
(COUT(ESR + RLOAD))-1
5TH ASYMPTOTE
VFB x VOUT -1 x gMV x RC x GMOD x (ESR || RLOAD)
6TH ASYMPTOTE
VFB x VOUT -1 x gMV x (CCC)-1 x GMOD x (ESR || RLOAD)
ᅄ3/! ख़ᒋ࢟ഗෝါࢯஂࡼ୍ણവሰ።
ྙਫDPVU ੪ࡍࡀᏴ୷ࡍࡼࢀࠈೊ࢟ᔜ)୷ࡍࡼFTS*Lj
࢟വࡼऔৈഃ࢛భถᆡ᎖ᆡᐐፄຫൈ)gDP >! ωDP03π*
ᒲᆍăᑚᒬ༽ౚሆLjభถኊገᏴDPNQਜ਼THOEᒄମೌ
औৈ)భኡࡼ*ቃ)ྏ࢟ޡݗDDD*Ljጲྜྷྯৈ࢛ă
ણവሰ።ࡼ႐୍ࣤதሣ)ᅄ3ᒦࡼ࠰ሣჅာ*᎖ཀྵࢾჅ
ገཇࡼᆡᐐፄຫൈ)݀ࢾ೫ޡݗᏄୈᒋ*ă୷ࢅࡼᆡ
ᐐፄຫൈถ৫ೂᆮࢾࡼܕણᔫLjࡣᑚဵጲ୷ൻࡼঌ
Ᏺਜ਼ၒྜྷ࢟Ꮞၾზሰ።ᆐࡔଥࡼăᄋᆡᐐፄຫൈᎌ
ᓐ᎖ᄋၾზሰ።Ljࡣ્፬ሰᇹᄻࡼᆮࢾቶ)༅ᏴፐႤ*ă
ږᑍਏಿLjᒙᆡᐐፄຫൈᆐ ≤ ఎਈຫൈࡼ2021 )࣪᎖
NBY26152Lj461lI{ࡼৼࢾఎਈຫൈభဧᆡᐐፄᒙᏴ
ࡍᏖ46lI{*ă
၅ሌཀྵࢾݧ൸ᔗ።ገཇࡼᇄᏎથဵᎌᏎൈᏄୈă
ઁLjږᑍ ܕણവǖଐ࢟ޡݗവ ݝॊᄋࡼݛᒾኡ
ᐋቃቧޡݗᏄୈLjࡻჅገཇࡼܕણຫൈሰ።ਜ਼ሤᆡ
Ꮍă
14
ܕણവǖଐ࢟ޡݗവ
2* ኡᐋჅገཇࡼᆡᐐፄຫൈLjኡᐋgDP ࢀ᎖gTX ࡼ2021
gDP ≈ 46lI{ă
3* ಽࠅၒણവࡼ႐୍ࣤதሣࡼᐐፄLjږᑍሆါኡᐋ
S D )ଣg DP ?! g Q2Ăg Q3 ਜ਼g [2Ljણവᔐᐐፄᒙᆐᆡ
ᐐፄ*ǖ
1=
×
VFB
× gMV × RC × GMOD × RLOAD
VOUT
1
2π × fCO × COUT × (ESR + RLOAD )
ፐࠥǖ
2π × fCO × COUT × (ESR + RLOAD )
V
RC = OUT ×
VFB
gMV × GMOD × RLOAD
______________________________________________________________________________________
ࢅ߅۾Ă4BĂ5/6Wᒗ39WၒྜྷĂ461lI{! QXN
ଢ଼ኹቯED.EDࢯஂLjดᒙఎਈ
V
2π × fCO × COUT
RC = OUT ×
VFB
gMV × GMOD
DDD ࡼལ࢛ဵଢ଼ࢅ೫ᑳৈᇹᄻࡼሤᆡᎽăܘኍཀྵۣྯ
ৈ࢛ᆡᒙᏐᏐި߲ჅገཇࡼᆡᐐፄຫൈLjጲିቃ
Ꭷᇹᄻણവሰ።ᏴᆡᐐፄࠀࡼሤઑᔫăྙਫDDD ቃ᎖
21qGLjᏴᑚቋଐႯᒦభă
ᒦLjWGC ࢀ᎖1/717Wă
ᒙྟࣅဟମ
4* ኡᐋDDăোჅገཇࡼሤᆡᎽLjᄰਭኡᐋᇹᄻጙ
ৈഃ࢛g[2 ࢾDD ࡼࡍቃăᄰޟLjᒙg[2 ࢅ᎖gDP ࡼ206Lj
భᄋᔗ৫ࡼሤᆡᎽă
fZ1 =
f
1
≤ CO
2π × CCRC
5
ፐࠥǖ
CC ≥
5
2π × fCO × RC
5* ྙਫFTSၒ߲ഃ࢛ࢅ᎖ఎਈຫൈࡼጙۍLjభݧऔৈ
ྏ࢟ޡݗDDD )భኡ*ቲࢎሿLjྙሆჅာǖ
1
1
= fP3 = fZ2 =
2π × CCCRC
2π × COUTESR
ྟࣅᄂቶభဧၒ߲࢟ኹદൻဍLjିቃࣅ໐ମࡼၒ
ྜྷ፻࢟ഗăಽሆါኡᐋDTT ࢟ྏLjࡻ໐ᆃࡼྟࣅ
ဟମuTTǖ
I ×t
CSS = SS SS
VFB
ྟࣅ࢟ഗJTT ᆐ6μB )࢜ቯᒋ*Ljၒ߲नౣ࢟ኹඡሢWGC ᆐ
1/717W )࢜ቯᒋ*ăࡩဧࡍ࢟ྏDPVU ဟLjྟࣅ໐ମభถ
્ࡉࡵ࢟ܟഗሢᒜăᆐཀྵۣᑵཀྵࡼྟࣅဟମuTTLjኡ
ᐋᔗ৫ࡍࡼDTT ጲ൸ᔗጲሆᄟୈǖ
CSS >> COUT ×
VOUT × ISS
(IHSCL _ MIN − IOUT ) × VFB
JITDM`NJO ᆐܟఎਈ࢟ഗሢࡼᔢቃᒋă
ፐࠥǖ
C
× ESR
CCC = OUT
RC
ྙਫFTSഃ࢛ިਭఎਈຫൈࡼ203Ljݧሆෂࢀါǖ
fP3 =
f
1
= SW
2π × CCCRC
2
ፐࠥǖ
CCC =
2
2π × fSW × RC
NBY26152ᄋᐐ༓ྲེࡼURGOॖᓤLjUB > ,81°Dဟభ
ྲࡉ2/777Xࡼൈăൡ።ࡩᏴᅪࡵೌݝTHOELj
ᔢੑࡵࡍෂ૩ށጲখ࿖ྲེăࡩበᆨࣞިਭ
,266°DဟLj߿खེਈۣࣥઐ)༿ݬఠེਈۣࣥઐݝॊ*ă
ݚݛᒾ
ᆐࡻࢅᐅĂᆮࢾࡼᔫቶถLjኍடဇଐQDCݚă༓
ೲᅎୀဧNBY26152ຶৰݚࡼۇLjጲࡻᔢଛቶถă
ྙਫܘኍቲኀখLjږᑍጲሆଐᏇᐌۣᑺQDCݚࡼ
ᒠǖ
2* ၒྜྷਜ਼ၒ߲࢟ྏೌࡵൈຳෂLjჅᎌ࢟
ྏೌࡵቧຳෂă
______________________________________________________________________________________
15
NBY26152
ᎅ᎖SMPBE Ꮠࡍ᎖FTSLjࢀါభጙ଼ݛછᆐǖ
NBY26152
ࢅ߅۾Ă4BĂ5/6Wᒗ39WၒྜྷĂ461lI{! QXN
ଢ଼ኹቯED.EDࢯஂLjดᒙఎਈ
3* W EEĂJOਜ਼TTࡼവ࢟ྏገభถణதJDहᒙLjሤ።
୭ݧᒇሣೌăൈຳෂ)ೌᒗQHOE*ਜ਼ቧ
ຳෂ)ೌᒗTHOE*ॊఎLjᏴణதၒྜྷവ࢟ྏऩ
ૄ࢛࣡ೌQHOEਜ਼THOEă
5* JOĂMYਜ਼QHOEॊܰೌࡵࡍෂ૩१ᄵཌᎮLjᎌᓐ
᎖JDྲེLjጙݛᄋൈă
4* ۣᑺࡍ࢟ഗᄰവሣభถ༦ăۣᑺఎਈ࢟ഗᄰ
വ୷݀ିቃᎅMYĂၒ߲࢟ྏጲૺၒྜྷ࢟ྏተ߅ࡼણ
വෂ૩ă
7* Ⴅఎਈஂ࢛ᔓሣ)ಿྙMYਜ਼CTU*ገᏐಭැঢࡼෝผཌ
Ꭾ)ಿྙGCਜ਼DPNQ*ă
6* ཀྵۣჅᎌनౣݧሣᒇೌLjनౣ࢟ᔜਜ਼ޡݗ
ᏄୈభถణதJDहᒙă
D
INPUT
4.5V TO 28V
RBST
47Ω
IN
BST
CIN
47μF
VDD
RPU
10kΩ
CBST
10nF
MAX15041
EN
L
4.7μH
OUTPUT = 3.3V
LX
COUT
22μF
CVDD
1μF
R1
45.3kΩ
1%
PGND
PGOOD
FB
PGOOD
SS
COMP
I.C.
SGND
CSS
0.01μF
R2
10.0kΩ
1%
RC
1.8kΩ
CCC
100pF
CC
12nF
ᅄ4/! ࢜ቯᔫ࢟വ)5/6Wᒗ39Wၒྜྷcvdlᓞધ*
ܭ2/! ᄰၒ߲࢟ኹᒙሆࡼ࢜ቯᏄୈᒋ
16
VOUT (V)
L (μH)
CC (nF)
RC (kΩ)
5.0
4.7
8
2.70
3.3
4.7
12
1.80
2.5
3.3
22
1.50
1.8
2.2
33
1.00
1.2
2.2
47
0.68
R1 and R2
Select R2 so that:
5kΩ ≤ R2 ≤ 50kΩ
Calculate R1 using the equation in the
Setting the Output Voltage section.
______________________________________________________________________________________
ࢅ߅۾Ă4BĂ5/6Wᒗ39WၒྜྷĂ461lI{! QXN
ଢ଼ኹቯED.EDࢯஂLjดᒙఎਈ
``````````````````````````````` ॖᓤቧᇦ
PROCESS: BiCMOS
ྙኊᔢதࡼॖᓤᅪተቧᇦਜ਼ݚLj༿އኯ china.maxim-ic.
com/packagesă༿ᓖፀLjॖᓤܠ൩ᒦࡼĐ,đĂĐ$đĐ.đஞܭာ
SpITᓨზăॖᓤᅄᒦభถ۞ݙᄴࡼᆘᓮᔊ९LjࡣॖᓤᅄᒑᎧॖ
ᓤᎌਈLjᎧSpITᓨზᇄਈă
ॖᓤಢቯ
ॖᓤܠ൩
ᅪተܠ
ݚܠ
16 TQFN-EP
T1633+4
21-0136
90-0031
______________________________________________________________________________________
17
NBY26152
``````````````````````````````` በຢቧᇦ
NBY26152
ࢅ߅۾Ă4BĂ5/6Wᒗ39WၒྜྷĂ461lI{! QXN
ଢ଼ኹቯED.EDࢯஂLjดᒙఎਈ
```````````````````````````````````````````````````````````````````````````` ኀࢿ಼ဥ
ኀࢿ
ኀࢿ྇໐
ႁී
ኀখ
0
7/09
ᔢ߱۾ۈă
1
3/10
ኀখ೫গၤĂBctpmvuf! Nbyjnvn! SbujohtĂFmfdusjdbm! DibsbdufsjtujdtĂ።ቧᇦ
ጲૺᅄ3ਜ਼ᅄ4ă
2
9/10
ৎቤ೫ Fmfdusjdbm! Dibsbdufsjtujdt ਜ਼ॖᓤቧᇦă
—
1, 2, 3, 8, 11–14,
16, 17
2, 17, 18
Nbyjn ۱யࠀူێ
۱ய 9439ቧረ ᎆᑶܠ൩ 211194
ॅ࢟જǖ911!921!1421
࢟જǖ121.7322 62::
ࠅᑞǖ121.7322 63::
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18 ____________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600
© 2010 Maxim Integrated Products
Nbyjn ဵ Nbyjn!Joufhsbufe!Qspevdut-!Jod/ ࡼᓖݿܪă
MAX15041 低成本、3A、4.5V至28V输入、350kHz PWM降压型DC-DC调节器,内置开关 - 概述
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Maxim > 产品 > 电源和电池管理 > MAX15041
MAX15041
低成本、3A、4.5V至28V输入、350kHz PWM降压型DC-DC调节器,内置开关
内置开关的低成本、3A、DC-DC调节器,理想用于低功率电源
概述 技术文档 定购信息 相关产品 用户说明 (0) 所有内容 状况
状况:生产中。
概述
数据资料
MAX15041是低成本、内置开关的同步DC-DC转换器,可提供高达3A的输出电流。MAX15041工作
在4.5V至28V输入电压范围,提供0.606V至VIN的90%的可调输出电压,可由两个外部电阻设
置。MAX15041理想用于分布式电源、预稳压、机顶盒、电视以及其它消费类电子应用。
MAX15041具有峰值电流模式PWM控制器,采用内部固定350kHz开关频率工作,且具有90%最大占
空比。电流模式控制架构简化了补偿设计,并可保证逐周期限流,快速响应输入电源及负载瞬变。高
增益跨导误差放大器允许使用II类补偿方案,便于外部补偿,可支持全陶瓷电容设计。
完整的数据资料
英文
下载 Rev. 2 (PDF, 1.4MB)
中文
下载 Rev. 2 (PDF, 920kB)
同步降压型调节器具有内部MOSFET,可提供比异步方案更高的效率;与分立式控制器方案相比大大
简化了设计。为便于设计,采用内置MOSFET降低EMI并减小电路板尺寸,通过减少外部元件数量提
供更高的可靠性。
MAX15041还具有热关断和过流保护功能(高边源出电流、低边吸入电流),带有欠压锁定功能的内
置5V LDO。此外,该器件上电进入预置输出,确保安全启动。
其它特性包括外部可调的软启动,可逐渐增大至输出电压并减小浪涌电流。独立的使能控制和电源就
绪信号允许灵活的电源排序。
MAX15041采用节省空间的大功率、3mm x 3mm、16引脚TQFN-EP封装,工作在-40°C至+85°C温度
范围。
现备有评估板:MAX15041EVKIT
关键特性
应用/使用
高达3A的连续输出电流
工作温度范围内保持±1%输出精度
4.5V至28V输入电压范围
输出电压在0.606V至0.9 x VIN范围内调节
内置170mΩ R DS-ON 高边功率开关和105mΩ R DS-ON 低边功率开关
350kHz固定开关频率
效率高达93%
逐周期过流保护
可编程软启动
采用低ESR陶瓷输出电容保持稳定输出
安全启动进入预置输出
使能输入和电源就绪输出
提供完整的过流和过热保护
VDD LDO欠压锁定
节省空间、增强散热的3mm x 3mm封装
消费类产品
分布式供电系统
前置调节器
机顶盒
电视
墙上适配器
xDSL调制解调器
Key Specifications: Step-Down Switching Regulators
Part
Number
Max.
IOUT
(A)
Max.
IOUT
(A)
max
≥
≤
25
3
3
VIN VIN VOUT VOUT
(V) (V) (V)
(V)
min max min
MAX15041 4.5
28
0.6
Output Adjust.
Method
http://china.maxim-ic.com/datasheet/index.mvp/id/6260[2010-12-14 7:49:36]
Resistor
DC-DC
Outputs
1
Oper.
Freq.
(kHz)
350
Smallest Available
Pckg.
Package/Pins
TQFN/16
Price
(mm 2 )
max w/pins
See
Notes
9.6
$2.90
@1k
MAX15041 低成本、3A、4.5V至28V输入、350kHz PWM降压型DC-DC调节器,内置开关 - 概述
查看所有Step-Down Switching Regulators (276)
Pricing Notes:
This pricing is BUDGETARY, for comparing similar parts. Prices are in U.S. dollars and subject to change. Quantity pricing may vary substantially and international prices may
differ due to local duties, taxes, fees, and exchange rates. For volume-specific prices and delivery, please see the price and availability page or contact an authorized
distributor.
图表
典型工作电路
更多信息
顶标
MAX15041
新品发布
[ 2009-12-16 ]
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参考文献: 19- 4815 Rev. 2; 2010- 09- 15
本页最后一次更新: 2010- 09- 15
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© 2010 Maxim Integrated Products版权所有
http://china.maxim-ic.com/datasheet/index.mvp/id/6260[2010-12-14 7:49:36]
19-4815; Rev 2; 9/10
KIT
ATION
EVALU
E
L
B
AVAILA
Low-Cost, 3A, 4.5V to 28V Input, 350kHz, PWM
Step-Down DC-DC Regulator with Internal Switches
The MAX15041 low-cost, synchronous DC-DC converter with internal switches delivers an output current up to
3A. The MAX15041 operates from an input voltage of
4.5V to 28V and provides an adjustable output voltage
from 0.6V to 90% of VIN, set with two external resistors.
The MAX15041 is ideal for distributed power systems,
preregulation, set-top boxes, television, and other consumer applications.
The MAX15041 features a peak-current-mode PWM controller with internally fixed 350kHz switching frequency
and a 90% maximum duty cycle. The current-mode control architecture simplifies compensation design, and
ensures a cycle-by-cycle current limit and fast response
to line and load transients. A high-gain transconductance
error amplifier allows flexibility in setting the external compensation by using a type II compensation scheme,
thereby allowing the use of all ceramic capacitors.
This synchronous buck regulator features internal
MOSFETs that provide better efficiency than asynchronous solutions, while simplifying the design relative to
discrete controller solutions. In addition to simplifying
the design, the integrated MOSFETs minimize EMI,
reduce board space, and provide higher reliability by
minimizing the number of external components.
The MAX15041 also features thermal shutdown and
overcurrent protection (high-side sourcing and low-side
sinking), and an internal 5V LDO with undervoltage
lockout. In addition, this device ensures safe startup
when powering into a prebiased output.
Other features include an externally adjustable soft-start
that gradually ramps up the output voltage and reduces
inrush current. Independent enable control and powergood signals allow for flexible power sequencing.
The MAX15041 is available in a space-saving, highpower, 3mm x 3mm, 16-pin TQFN-EP package and is
fully specified from -40°C to +85°C.
Features
o
o
o
o
o
o
o
o
o
o
o
o
o
o
o
Up to 3A of Continuous Output Current
±1% Output Accuracy Over Temperature
4.5V to 28V Input Voltage Range
Adjustable Output Voltage Range from 0.606V to
0.9 x VIN
Internal 170mΩ RDS-ON High-Side and 105mΩ
RDS-ON Low-Side Power Switches
Fixed 350kHz Switching Frequency
Up to 93% Efficiency
Cycle-By-Cycle Overcurrent Protection
Programmable Soft-Start
Stable with Low-ESR Ceramic Output Capacitors
Safe Startup into Prebiased Output
Enable Input and Power-Good Output
Fully Protected Against Overcurrent and
Overtemperature
VDD LDO Undervoltage Lockout
Space-Saving, Thermally Enhanced, 3mm x 3mm
Package
Ordering Information
PART
MAX15041ETE+
TEMP RANGE
-40°C to +85°C 16 TQFN-EP*
INPUT
12V
IN
BST
OUTPUT
1.8V AT 3A
EN
MAX15041
LX
VDD
Wall Adapters
PGND
Preregulators
Set-Top Boxes
Consumer Products
AGV
Typical Operating Circuit
Distributed Power Systems
xDSL Modems
TOP
MARK
+Denotes a lead(Pb)-free/RoHS-compliant package.
*EP = Exposed pad.
Applications
Televisions
PINPACKAGE
PGOOD
PGOOD
FB
SS
COMP
SGND
________________________________________________________________ Maxim Integrated Products
For pricing, delivery, and ordering information, please contact Maxim Direct at 1-888-629-4642,
or visit Maxim’s website at www.maxim-ic.com.
1
MAX15041
General Description
MAX15041
Low-Cost, 3A, 4.5V to 28V Input, 350kHz, PWM
Step-Down DC-DC Regulator with Internal Switches
ABSOLUTE MAXIMUM RATINGS
IN to SGND.............................................................-0.3V to +30V
EN to SGND .................................................-0.3V to (VIN + 0.3V)
LX to PGND ................................-0.3V to min (+30V, VIN + 0.3V)
LX to PGND .....................-1V to min (+30V, VIN + 0.3V) for 50ns
PGOOD to SGND .....................................................-0.3V to +6V
VDD to SGND............................................................-0.3V to +6V
COMP, FB, SS to SGND..............-0.3V to min (+6V, VDD + 0.3V)
BST to LX .................................................................-0.3V to +6V
BST to SGND .........................................................-0.3V to +36V
SGND to PGND ....................................................-0.3V to +0.3V
LX Current (Note 1) ....................................................-5A to +8A
Converter Output Short-Circuit Duration ...................Continuous
Continuous Power Dissipation (TA = +70°C)
16-Pin TQFN (derate 14.7mW/°C above +70°C)
Multilayer Board .........................................................1666mW
Package Thermal Resistance (Note 2)
θJA ................................................................................48°C/W
θJC ..................................................................................7°C/W
Operating Temperature Range ..........................-40°C to +85°C
Junction Temperature .....................................................+150°C
Storage Temperature Range ............................-65°C to +150°C
Lead Temperature (soldering, 10s) .................................+300°C
Soldering Temperature (reflow) .......................................+260°C
Note 1: LX has internal clamp diodes to PGND and IN. Applications that forward bias these diodes should take care not to exceed
the IC’s package power dissipation.
Note 2: Package thermal resistances were obtained using the method described in JEDEC specification JESD51-7, using a fourlayer board. For detailed information on package thermal considerations, refer to www.maxim-ic.com/thermal-tutorial.
Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional
operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to
absolute maximum rating conditions for extended periods may affect device reliability.
ELECTRICAL CHARACTERISTICS
(VIN = 12V, CVDD = 1µF, CIN = 22µF, TA = TJ = -40°C to +85°C, typical values are at TA = +25°C, unless otherwise noted.) (Note 3)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
28
V
mA
STEP-DOWN CONVERTER
Input-Voltage Range
VIN
Quiescent Current
IIN
Shutdown Input Supply Current
4.5
Not switching
2.1
4
VEN = 0V, VDD regulated by internal
LDO
2
12
VEN = 0V, VIN = VDD = 5V
18
28
VEN rising
1.4
µA
ENABLE INPUT
EN Shutdown Threshold Voltage
EN Shutdown Voltage Hysteresis
EN Lockout Threshold Voltage
EN Input Current
VEN_SHDN
VEN_HYST
VEN_LOCK
V
100
VEN rising
1.7
1.95
mV
2.15
100
VEN_LOCK_HYST
V
mV
IEN
VEN = 2.9V
2
5.3
9
µA
VPGOOD_TH
VFB rising
540
560
584
mV
POWER-GOOD OUTPUT
PGOOD Threshold
PGOOD Threshold Hysteresis
VPGOOD_HYST
PGOOD Output Low Voltage
VPGOOD_OL
IPGOOD = 5mA, VFB = 0.5V
35
IPGOOD
VPGOOD = 5V, VFB = 0.7V
10
nA
1.6
mS
PGOOD Leakage Current
15
mV
100
mV
ERROR AMPLIFIER
Error Amplifier
Transconductance
gMV
Error Amplifier Voltage Gain
AVEA
FB Set-Point Accuracy
VFB
FB Input Bias Current
IFB
2
90
600
606
dB
612
VFB = 0.5V
-100
+100
VFB = 0.7V
-100
+100
_______________________________________________________________________________________
mV
nA
Low-Cost, 3A, 4.5V to 28V Input, 350kHz, PWM
Step-Down DC-DC Regulator with Internal Switches
(VIN = 12V, CVDD = 1µF, CIN = 22µF, TA = TJ = -40°C to +85°C, typical values are at TA = +25°C, unless otherwise noted.) (Note 3)
PARAMETER
SYMBOL
CONDITIONS
SS Current
ISS
VSS = 0.45V, sourcing
SS Discharge Resistance
RSS
ISS = 10mA, sinking, VEN = 1.6V
MIN
TYP
MAX
UNITS
4.5
5
5.5
µA
SS Prebiased Mode Stop Voltage
Current Sense to COMP
Transconductance
GMOD
COMP Clamp Low
VFB = 0.7V
PWM Compensation Ramp Valley
6
Ω
0.65
V
9
S
0.68
V
830
mV
PWM CLOCK
Switching Frequency
fSW
Maximum Duty Cycle
D
315
Minimum Controllable On-Time
350
385
kHz
90
%
150
ns
INTERNAL LDO OUTPUT (VDD)
VDD Output Voltage
VDD
IVDD = 1mA to 25mA, VIN = 6.5V
VDD Short-Circuit Current
VIN = 6.5V
LDO Dropout Voltage
IVDD = 25mA, VDD drops by -2%
VDD Undervoltage Lockout
Threshold
VUVLO_TH
VDD Undervoltage Lockout
Hysteresis
VUVLO_HYST
4.75
30
VDD rising
5.1
5.5
80
V
mA
250
600
mV
4
4.25
V
150
mV
POWER SWITCH
LX On-Resistance
High-side switch, ILX = 1A
170
305
Low-side switch, ILX = 1A
105
175
6
7.2
High-Side Switch Source
Current-Limit Threshold
5
Low-Side Switch Sink
Current-Limit Threshold
LX Leakage Current
BST Leakage Current
-3
VBST = 33V, VIN = VLX = 28V
10
VBST = 5V, VIN = 28V, VLX = 0V
10
VBST = 33V, VIN = VLX = 28V
10
mΩ
A
A
nA
nA
THERMAL SHUTDOWN
Thermal-Shutdown Threshold
Thermal-Shutdown Hysteresis
Rising
+155
°C
20
°C
HICCUP PROTECTION
Blanking Time
16 x SoftStart Time
Note 3: Specifications are 100% production tested at TA = +25°C. Limits over the operating temperature range are guaranteed by
design and characterization.
_______________________________________________________________________________________
3
MAX15041
ELECTRICAL CHARACTERISTICS (continued)
Typical Operating Characteristics
(VIN = 12V, VOUT = 3.3V, CVDD = 1µF, CIN = 22µF, TA = +25°C, circuit of Figure 3 (see Table 1 for values), unless otherwise specified.)
EFFICIENCY vs. LOAD CURRENT
VOUT = 5.0V
75
VOUT = 3.3V
70
VOUT = 2.5V
65
VOUT = 1.8V
VOUT = 1.2V
60
55
50
85
80
75
VOUT = 3.3V
70
65
VOUT = 2.5V
60
VOUT = 1.8V
55
VOUT = 1.2V
50
0.5
1.0
1.5
2.0
3.0
2.5
-0.2
-0.4
-0.6
-0.8
-1.0
-1.2
0
0.5
1.0
1.5
2.0
3.0
2.5
0
0.5
1.0
1.5
2.5
LOAD CURRENT (A)
LOAD CURRENT (A)
LOAD-TRANSIENT WAVEFORMS
NORMALIZED OUTPUT VOLTAGE
vs. TEMPERATURE
NORMALIZED OUTPUT VOLTAGE
vs. TEMPERATURE
1.002
ILOAD
2A/div
VOUT
AC-COUPLED
200mV/div
VPGOOD
5V/div
NORMALIZED OUTPUT VOLTAGE
ILOAD = 0A
1.001
1.000
0.999
0.998
0.997
1.004
ILOAD = 2A
NORMALIZED OUTPUT VOLTAGE
MAX15041 toc04
0.996
-40
1.002
1.000
0.998
0.996
0.994
-15
10
35
-15
-40
85
60
10
SWITCHING FREQUENCY
vs. INPUT VOLTAGE
FB SET POINT vs.TEMPERATURE
606
604
MAX15041 toc08
MAX15041 toc07
385
375
FREQUENCY (kHz)
FB SET POINT (mV)
608
35
TEMPERATURE (NC)
TEMPERATURE (NC)
610
365
355
345
TA = +85NC
335
TA = +25NC
TA = -40NC
602
325
600
315
-40
-15
10
35
TEMPERATURE (NC)
60
85
3.0
0.992
0.995
200µs/div
4
2.0
LOAD CURRENT (A)
MAX15041 toc05
0
0
MAX15041 toc06
80
EFFICIENCY (%)
85
MAX15041 toc03
90
OUTPUT-VOLTAGE REGULATION (%)
90
VIN = 5V
95
0.2
MAX15041 toc02
100
MAX15041 toc01
VIN = 12V
95
OUTPUT-VOLTAGE REGULATION
vs. LOAD CURRENT
EFFICIENCY vs. LOAD CURRENT
100
EFFICIENCY (%)
MAX15041
Low-Cost, 3A, 4.5V to 28V Input, 350kHz, PWM
Step-Down DC-DC Regulator with Internal Switches
0
5
10
15
20
INPUT VOLTAGE (V)
_______________________________________________________________________________________
25
60
85
Low-Cost, 3A, 4.5V to 28V Input, 350kHz, PWM
Step-Down DC-DC Regulator with Internal Switches
INPUT SUPPLY CURRENT
vs. INPUT VOLTAGE
13
12
8
7
6
5
4
3
2
11
4.0
MAX15041 toc11
9
SHUTDOWN CURRENT (FA)
14
10
MAX15041 toc10
L = 4.7FH
ILOAD = 0A
SHUTDOWN CURRENT (FA)
MAX15041 toc09
INPUT SUPPLY CURRENT (mA)
16
15
SHUTDOWN CURRENT
vs. TEMPERATURE
SHUTDOWN CURRENT
vs. INPUT VOLTAGE
3.5
3.0
2.5
2.0
1.5
1
1.0
0
10
0
5
10
15
20
0
25
5
10
15
20
25
-40
-15
SHUTDOWN WAVEFORMS
10
35
85
OUTPUT SHORT-CIRCUIT WAVEFORMS
MAX15041 toc12
MAX15041 toc13
VEN
5V/div
VOUT
2V/div
IIN
5A/div
VOUT
2V/div
IL
5A/div
IL
2A/div
VPGOOD
5V/div
100µs/div
VSS
2V/div
10µs/div
SOFT-START WAVEFORMS
SWITCHING WAVEFORMS
MAX15041 toc15
MAX15041 toc14
VEN
5V/div
VLX
10V/div
VOUT
2V/div
IL
2A/div
IL
2A/div
VOUT
AC-COUPLED
50mV/div
1µs/div
60
TEMPERATURE (NC)
INPUT VOLTAGE (V)
INPUT VOLTAGE (V)
VPGOOD
5V/div
400µs/div
_______________________________________________________________________________________
5
MAX15041
Typical Operating Characteristics (continued)
(VIN = 12V, VOUT = 3.3V, CVDD = 1µF, CIN = 22µF, TA = +25°C, circuit of Figure 3 (see Table 1 for values), unless otherwise specified.)
Typical Operating Characteristics (continued)
(VIN = 12V, VOUT = 3.3V, CVDD = 1µF, CIN = 22µF, TA = +25°C, circuit of Figure 3 (see Table 1 for values), unless otherwise specified.)
SOFT-START TIME
vs. CAPACITANCE
STARTUP INTO PREBIASED OUTPUT
MAX15041 toc17
MAX15041 toc16
1000
SOFT-START TIME (ms)
VEN
5V/div
100
VOUT
2V/div
10
IL
2A/div
1
IOUT
2A/div
0.1
1
10
100
400µs/div
1000
CSS (nF)
MAX15041 toc18
3.2
VEN
5V/div
VOUT
2V/div
IL
5A/div
IOUT
5A/div
MAX15041 toc19
MAXIMUM LOAD CURRENT
vs. AMBIENT TEMPERATURE
STARTUP INTO PREBIASED OUTPUT
MAXIMUM LOAD CURRENT (A)
MAX15041
Low-Cost, 3A, 4.5V to 28V Input, 350kHz, PWM
Step-Down DC-DC Regulator with Internal Switches
VIN = 5V
TJ P +150NC
3.0
2.8
VOUT = 3.3V
2.6
VOUT = 2.5V
2.4
VOUT = 1.8V
VOUT = 1.2V
2.2
2.0
400µs/div
5
15
25
35
45
55
65
75
AMBIENT TEMPERATURE (NC)
6
_______________________________________________________________________________________
85
Low-Cost, 3A, 4.5V to 28V Input, 350kHz, PWM
Step-Down DC-DC Regulator with Internal Switches
MAXIMUM LOAD CURRENT (A)
VIN = 12V
TJ P +150NC
3.0
3.2
MAX15041 toc20
2.8
VOUT = 3.3V
VOUT = 2.5V
2.6
VOUT = 1.8V
2.4
VOUT = 1.2V
VIN = 28V
TJ P +150NC
3.0
2.8
VOUT = 1.2V
2.6
VOUT = 3.3V
VOUT = 2.5V
2.4
VOUT = 1.8V
2.2
2.2
2.0
2.0
5
15
25
35
45
55
65
75
5
85
15
DEVICE POWER DISSIPATION
vs. LOAD CURRENT
VIN = 12V
45
55
65
75
85
3.0
VOUT = 3.3V
VIN = 5V
2.5
POWER DISSIPATION (W)
POWER DISSIPATION (W)
2.5
VOUT = 2.5V
VOUT = 1.8V
1.5
35
DEVICE POWER DISSIPATION
vs. LOAD CURRENT
MAX15041 toc22
3.0
2.0
25
AMBIENT TEMPERATURE (NC)
AMBIENT TEMPERATURE (NC)
VOUT = 1.2V
1.0
0.5
MAX15041 toc23
MAXIMUM LOAD CURRENT (A)
3.2
MAX15041 toc21
MAXIMUM LOAD CURRENT
vs. AMBIENT TEMPERATURE
MAXIMUM LOAD CURRENT
vs. AMBIENT TEMPERATURE
VOUT = 3.3V
VOUT = 2.5V
2.0
VOUT = 1.8V
VOUT = 1.2V
1.5
1.0
0.5
0
0
0
0.5
1.0
1.5
2.0
LOAD CURRENT (A)
2.5
3.0
0
0.5
1.0
1.5
2.0
2.5
3.0
LOAD CURRENT (A)
_______________________________________________________________________________________
7
MAX15041
Typical Operating Characteristics (continued)
(VIN = 12V, VOUT = 3.3V, CVDD = 1µF, CIN = 22µF, TA = +25°C, circuit of Figure 3 (see Table 1 for values), unless otherwise specified.)
Low-Cost, 3A, 4.5V to 28V Input, 350kHz, PWM
Step-Down DC-DC Regulator with Internal Switches
MAX15041
Pin Configuration
LX
LX
LX
BST
TOP VIEW
12
11
10
9
PGND 13
PGND 14
MAX15041
IN 15
*EP
1
2
3
4
PGOOD
EN
COMP
+
VDD
IN 16
8
I.C.
7
SGND
6
SS
5
FB
TQFN
*EXPOSED PAD, CONNECT TO SGND.
Pin Description
8
PIN
NAME
FUNCTION
1
VDD
2
PGOOD
3
EN
4
COMP
5
FB
Feedback Input. Connect FB to the center tap of an external resistor-divider from the output to SGND to set
the output voltage from 0.606V to 90% of VIN.
6
SS
Soft-Start Input. Connect a capacitor from SS to SGND to set the soft-start time (see the Setting the SoftStart Time section).
7
SGND
8
I.C.
Internally Connected. Connect to SGND.
9
BST
High-Side MOSFET Driver Supply. Bypass BST to LX with a 10nF capacitor. Connect an external diode
(see the Diode Selection section) from VDD to BST.
10, 11, 12
LX
13, 14
PGND
15, 16
IN
Input Power Supply. Input supply range is from 4.5V to 28V. Bypass with a ceramic capacitor of at least
22µF to PGND.
—
EP
Exposed Pad. Connect to SGND externally. Solder the exposed pad to a large contiguous copper plane to
maximize thermal performance.
Internal LDO 5V Output. Supply input for the internal analog core. Bypass with a ceramic capacitor of at
least 1µF to SGND. See Figure 3.
Power-Good Open-Drain Output. PGOOD goes low if FB is below 545mV.
Enable Input. EN is a digital input that turns the regulator on and off. Drive EN high to turn on the regulator.
Connect to IN for always-on operations.
Voltage Error-Amplifier Output. Connect the necessary compensation network from COMP to SGND.
Analog Ground. Connect to PGND plane at one point near the input bypass capacitor return terminal.
Inductor Connection. Connect the LX pin to the switched side of the inductor. LX is high impedance when
the IC is in shutdown mode, thermal shutdown mode, or VDD is below the UVLO threshold.
Power Ground. Connect to the SGND PCB copper plane at one point near the input bypass capacitor
return terminal.
_______________________________________________________________________________________
Low-Cost, 3A, 4.5V to 28V Input, 350kHz, PWM
Step-Down DC-DC Regulator with Internal Switches
ENABLE CONTROL
AND THERMAL
SHUTDOWN
EN
5V LDO
VDD
UVLO
COMPARATOR
4V
MAX15041
VDD
BIAS
GENERATOR
BST
CURRENT-SENSE/CURRENT-LIMIT
AMPLIFIER
IN
LX
VOLTAGE
REFERENCE
N
CONTROL
LOGIC AND
SINK LIMIT
0.65V
LX
VDD
STRONG PREBIAS
COMPARATOR
5µA
N
PWM
COMPARATOR
0.606V
PGND
SS
FB
ERROR
AMPLIFIER
Σ
OSCILLATOR
COMP
PGOOD
SGND
N
0.560V RISING,
0.545V FALLING
POWER-GOOD
COMPARATOR
_______________________________________________________________________________________
9
MAX15041
Simplified Block Diagram
MAX15041
Low-Cost, 3A, 4.5V to 28V Input, 350kHz, PWM
Step-Down DC-DC Regulator with Internal Switches
Detailed Description
The MAX15041 is a high-efficiency, peak-currentmode, step-down DC-DC converter with integrated
high-side (170mΩ, typ) and low-side (105mΩ, typ)
power switches. The output voltage is set from 0.606V
to 0.9 x VIN by using an adjustable, external resistive
divider and can deliver up to 3A load current. The 4.5V
to 28V input voltage range makes the device ideal for
distributed power systems, notebook computers, and
preregulation applications.
The MAX15041 features a PWM, internally fixed 350kHz
switching frequency with a 90% maximum duty cycle.
PWM current-mode control allows for an all-ceramic
capacitor solution. The MAX15041 comes with a highgain transconductance error amplifier. The currentmode control architecture simplifies compensation
design and ensures a cycle-by-cycle current limit and
fast reaction to line and load transients. The low
RDS-ON, on-chip, MOSFET switches ensure high efficiency at heavy loads and minimize critical inductances, reducing layout sensitivity.
The MAX15041 also features thermal shutdown and
overcurrent protection (high-side sourcing and low-side
sinking), and an internal 5V, LDO with undervoltage
lockout. An externally adjustable voltage soft-start
gradually ramps up the output voltage and reduces
inrush current. Independent enable control and powergood signals allow for flexible power sequencing. The
MAX15041 also provides the ability to start up into a
prebiased output, below or above the set point.
Controller Function–PWM Logic
The MAX15041 operates at a constant 350kHz switching frequency. When EN is high, after a brief settling
time, PWM operation starts when VSS crosses the FB
voltage, at the beginning of soft-start.
The first operation is always a high-side MOSFET turnon, at the beginning of the clock cycle. The high-side
MOSFET is turned off when:
1) COMP voltage crosses the internal current-mode
ramp waveform, which is the sum of the compensation ramp and the current-mode ramp derived from
the inductor current waveform (current-sense block).
10
2) The high-side MOSFET current limit is reached.
3) The maximum duty cycle of 90% is reached.
Then, the low-side MOSFET turns on; the low-side
MOSFET turns off when the clock period ends.
Starting into a Prebiased Output
The MAX15041 is capable of safely soft-starting into a
prebiased output without discharging the output
capacitor. Starting up into a prebiased condition, both
low-side and high-side MOSFETs remain off to avoid
discharging the prebiased output. PWM operation
starts only when the SS voltage crosses the FB voltage.
The MAX15041 is also capable of soft-starting into an
output prebiased above the OUT nominal set point. In
this case, forced PWM operation starts when SS voltage reaches 0.65V (typ).
In case of a prebiased output, below or above the OUT
nominal set point, if the low-side MOSFET sink current
reaches the sink current limit (-3A, typ), the low-side
MOSFET turns off before the end of the clock period
and the high-side MOSFET turns on until one of the following conditions happens:
1) High-side MOSFET source current hits the reduced
high-side MOSFET current limit (0.75A, typ); in this
case, the high-side MOSFET is turned off for the
remaining clock period.
2) The clock period ends.
Enable Input and Power-Good Output
The MAX15041 features independent device enable
control and power-good signals that allow for flexible
power sequencing. The enable input (EN) is an input
with a 1.95V (typ) threshold that controls the regulator.
Assert a voltage exceeding the threshold on EN to
enable the regulator, or connect EN to IN for always-on
operations. Power-good (PGOOD) is an open-drain
output that deasserts (goes high impedance) when VFB
is above 560mV (typ), and asserts low if VFB is below
545mV (typ).
When the EN voltage is higher than 1.4V (typ) and
lower than 1.95V (typ), most of the internal blocks are
disabled, only an internal coarse preregulator, including the EN accurate comparator, is kept on.
______________________________________________________________________________________
Low-Cost, 3A, 4.5V to 28V Input, 350kHz, PWM
Step-Down DC-DC Regulator with Internal Switches
Internal LDO (VDD)
The MAX15041 has an internal 5.1V (typ) LDO. VDD is
externally compensated with a minimum 1µF, low-ESR
ceramic capacitor. The VDD voltage is used to supply
the low-side MOSFET driver, and to supply the internal
control logic. When the input supply (IN) is below 4.5V,
VDD is 50mV (typ) lower than IN. The VDD output current limit is 80mA (typ) and an UVLO circuit inhibits
switching when VDD falls below 3.85V (typ).
Error Amplifier
A high-gain error amplifier provides accuracy for the voltage feedback loop regulation. Connect the necessary
compensation network between COMP and SGND (see
the Compensation Design Guidelines section). The erroramplifier transconductance is 1.6mS (typ). COMP clamp
low is set to 0.68V (typ), just below the PWM ramp compensation valley, helping COMP to rapidly return to correct set point during load and line transients.
PWM Comparator
The PWM comparator compares COMP voltage to the
current-derived ramp waveform (LX current to COMP voltage transconductance value is 9A/V, typ.). To avoid instability due to subharmonic oscillations when the duty cycle
is around 50% or higher, a compensation ramp is added
to the current-derived ramp waveform. The compensation
ramp slope (0.45V x 350kHz) is equivalent to half of the
inductor current down slope in the worst case (load 3A,
current ripple 30% and maximum duty cycle operation of
90%). Compensation ramp valley is set at 0.83V (typ).
Overcurrent Protection
and Hiccup Mode
When the converter output is shorted or the device is
overloaded, the high-side MOSFET current-limit event
(6A, typ) turns off the high-side MOSFET and turns on
the low-side MOSFET. In addition, it discharges the SS
capacitor, CSS for a fixed period of time (∆T0 = 70ns,
typ). If the overcurrent condition persists, SS is pulled
below 0.606V and a hiccup event is triggered.
During a hiccup event, high-side and low-side
MOSFETs are kept off, and COMP is pulled low for a
period equal to 16 times the nominal soft-start time
(blanking time). This is obtained by charging SS from 0
to 0.606V with a 5µA (typ) current, and then slowly discharging it back to 0V with a 333nA (typ) current. After
the blanking time has elapsed, the device attempts to
restart. If the overcurrent fault has cleared, the device
resumes normal operation, otherwise a new hiccup
event is triggered (see the Output Short-Circuit
Waveforms in the Typical Operating Characteristics).
Thermal-Shutdown Protection
The MAX15041 contains an internal thermal sensor that
limits the total power dissipation in the device and protects it in the event of an extended thermal fault condition. When the die temperature exceeds +155°C (typ),
the thermal sensor shuts down the device, turning off
the DC-DC converter and the LDO regulator to allow
the die to cool. After the die temperature falls by 20°C
(typ), the device restarts, using the soft-start sequence.
Applications Information
Setting the Output Voltage
Connect a resistive divider (R1 and R2, see Figures 1
and 3) from OUT to FB to SGND to set the DC-DC converter output voltage. Choose R1 and R2 so that the DC
errors due to the FB input bias current do not affect the
output-voltage precision. With lower value resistors, the
DC error is reduced, but the amount of power consumed
in the resistive divider increases. A typical tradeoff value
for R2 is 10kΩ, but values between 5kΩ and 50kΩ are
acceptable. Once R2 is chosen, calculate R1 using:
⎛V
⎞
R1 = R2 × ⎜ OUT − 1⎟
⎝ VFB
⎠
where the feedback threshold voltage VFB = 0.606V
(typ).
______________________________________________________________________________________
11
MAX15041
Programmable Soft-Start (SS)
The MAX15041 utilizes a soft-start feature to slowly ramp
up the regulated output voltage to reduce input inrush
current during startup. Connect a capacitor from SS to
SGND to set the startup time (see the Setting the SoftStart Time section for capacitor selection details).
MAX15041
Low-Cost, 3A, 4.5V to 28V Input, 350kHz, PWM
Step-Down DC-DC Regulator with Internal Switches
Inductor Selection
A larger inductor value results in reduced inductor ripple
current, leading to a reduced output ripple voltage.
However, a larger inductor value results in either a larger
physical size or a higher series resistance (DCR) and a
lower saturation current rating. Typically, inductor value
is chosen to have current ripple equal to 30% of load
current. Choose the inductor with the following formula:
⎛ V
⎞
VOUT
L=
× 1 − OUT ⎟
fSW × ∆IL ⎜⎝
VIN ⎠
where fSW is the internally fixed 350kHz switching frequency, and ∆IL is the estimated inductor ripple current
(typically set to 0.3 x I LOAD ). In addition, the peak
inductor current, IL_PK, must always be below both the
minimum high-side MOSFET current-limit value,
IHSCL_MIN (5A, typ), and the inductor saturation current
rating, IL_SAT. Ensure that the following relationship is
satisfied:
1
IL _ PK = ILOAD + × ∆IL < min(IHSCL _ MIN ,IL _ SAT )
2
Diode Selection
The MAX15041 requires an external bootstrap steering
diode. Connect the diode between VDD and BST. The
diode should have a reverse voltage rating, higher than
the converter input voltage and a 200mA minimum current rating. Typically, a fast switching or Schottky diode
is used in this application, but a simple low-cost diode
(1N4007) suffices.
Input Capacitor Selection
For a step-down converter, input capacitor CIN helps to
keep the DC input voltage steady, in spite of discontinuous input AC current. Low-ESR capacitors are preferred to minimize the voltage ripple due to ESR.
For ceramic capacitors, ESR contribution is negligible:
RESR _ COUT <<
1
8 × fSW × COUT
For tantalum or electrolytic capacitors, ESR contribution
is dominant:
1
RESR _ COUT >>
8 × fSW × COUT
Compensation Design Guidelines
The MAX15041 uses a fixed-frequency, peak-currentmode control scheme to provide easy compensation
and fast transient response. The inductor peak current is
monitored on a cycle-by-cycle basis and compared to
the COMP voltage (output of the voltage error amplifier).
The regulator’s duty-cycle is modulated based on the
inductor’s peak current value. This cycle-by-cycle control of the inductor current emulates a controlled current
source. As a result, the inductor’s pole frequency is
shifted beyond the gain-bandwidth of the regulator.
System stability is provided with the addition of a simple series capacitor-resistor from COMP to SGND. This
pole-zero combination serves to tailor the desired
response of the closed-loop system.
The basic regulator loop consists of a power modulator
(comprising the regulator’s pulse-width modulator,
compensation ramp, control circuitry, MOSFETs, and
inductor), the capacitive output filter and load, an output feedback divider, and a voltage-loop error amplifier
with its associated compensation circuitry. See Figure 1
for a graphical representation.
The average current through the inductor is expressed as:
IL = GMOD × VCOMP
Size CIN using the following formula:
ILOAD
V
CIN =
× OUT
fSW × ∆VIN _ RIPPLE
VIN
Output-Capacitor Selection
Low-ESR capacitors are recommended to minimize the
voltage ripple due to ESR. Total output-voltage peak-topeak ripple is estimated by the following formula:
∆VOUT =
12
⎞
⎛ V
⎞ ⎛
VOUT
1
× 1 − OUT ⎟ × ⎜ RESR _ COUT +
fSW × L ⎜⎝
VIN ⎠ ⎝
8 × fSW × COUT ⎟⎠
where IL is the average inductor current and GMOD is
the power modulator’s transconductance. For a buck
converter:
VOUT = R LOAD × IL
where R LOAD is the equivalent load resistor value.
Combining the two previous equations, the power modulator’s transfer function in terms of VOUT with respect
to VCOMP is:
VOUT
R
×I
= LOAD L = RLOAD × GMOD
VCOMP
⎛ IL ⎞
⎜⎝ G
⎟
MOD ⎠
______________________________________________________________________________________
Low-Cost, 3A, 4.5V to 28V Input, 350kHz, PWM
Step-Down DC-DC Regulator with Internal Switches
COMPENSATION
RAMP
VOUT
Σ
FB
R1
MAX15041
POWER MODULATOR
ERROR AMPLIFIER
FEEDBACK
DIVIDER
OUTPUT FILTER
AND LOAD
VIN
gMC
COMP
QHS
VOUT
L0
DCR
CONTROL
LOGIC
R2
ROUT
gMV
RC
PWM
COMPARATOR
*CCC
IL
QLS
ESR
RLOAD
COUT
CC
VCOMP
GMOD
VOUT
IL
ROUT = AVEA/gMV
*CCC IS OPTIONAL.
REF
NOTE: THE GMOD STAGE SHOWN ABOVE MODELS THE AVERAGE CURRENT OF
THE INDUCTOR INJECTED INTO THE OUTPUT LOAD. THIS REPRESENTS A
SIMPLIFICATION FOR THE POWER MODULATOR STAGE DRAWN ABOVE.
Figure 1. Peak Current-Mode Regulator Transfer Model
Having defined the power modulator’s transfer function
gain, the total system loop gain can be written as follows (see Figure 1):
α=
ROUT × ( sCCRC + 1)
⎡⎣s ( CC + CCC ) (RC + ROUT ) + 1⎤⎦ × ⎡⎣s ( CC || CCC )(RC || ROUT ) + 1⎤⎦
β = GMOD ×
(sCOUTESR + 1)
RLOAD ×
⎡⎣sCOUT (ESR + RLOAD ) + 1⎤⎦
R2
A
Gain =
× VEA × α × β
R1 + R2 ROUT
where ROUT is the quotient of the error amplifier’s DC
gain, AVEA, divided by the error amplifier’s transconductance, gMV; ROUT is much larger than RC and CC is
much larger than CCC.
Rewriting:
Gain =
(sCCRC + 1)
VFB
A VEA ×
VOUT
⎡
⎛ A VEA ⎞ ⎤
+ 1⎥ × ( sCCCRC + 1)
⎢sCC ⎜
⎝ gMV ⎟⎠ ⎦
⎣
× GMODRLOAD ×
The dominate poles and zeros of the transfer loop gain
is shown below:
fP1 =
2π × 10
gMV
A VEA [dB] / 20
fP3 =
1
2π × CCCRC
fZ2 =
1
2π × COUTESR
× CC
fZ1 =
fP2 =
1
2π × COUT (ESR + RLOAD )
1
2π × CCRC
The order of pole-zero occurrence is:
fP1 < fP2 < fZ1 < fZ2 ≤ fP3
Note under heavy load, fP2, may approach fZ1.
A graphical representation of the asymptotic system
closed-loop response, including the dominant pole and
zero locations is shown in Figure 2.
(sCOUTESR + 1)
⎡⎣sCOUT (ESR + RLOAD ) + 1⎤⎦
______________________________________________________________________________________
13
MAX15041
Low-Cost, 3A, 4.5V to 28V Input, 350kHz, PWM
Step-Down DC-DC Regulator with Internal Switches
GAIN
1ST ASYMPTOTE
VFB x VOUT -1 x 10AVEA[dB]/20 x GMOD x RLOAD
2ND ASYMPTOTE
VFB x VOUT -1 x gMV x (CC)-1 x GMOD x RLOAD
3RD ASYMPTOTE
VFB x VOUT -1 x gMV x (CC)-1 x GMOD x RLOAD x ( COUT(ESR + RLOAD))-1
4TH ASYMPTOTE
VFB x VOUT -1 x gMV x RC x GMOD x RLOAD x (COUT(ESR + RLOAD))-1
3RD POLE
(CCCRC)-1
2ND ZERO
(COUTESR)-1
UNITY
1ST POLE
gMV x (10AVEA[dB]/20 CC)-1
RAD/S
1ST ZERO
(CCRC)-1
CO
2ND POLE
(COUT(ESR + RLOAD))-1
5TH ASYMPTOTE
VFB x VOUT -1 x gMV x RC x GMOD x (ESR || RLOAD)
6TH ASYMPTOTE
VFB x VOUT -1 x gMV x ( CCC)-1 x GMOD x (ESR || RLOAD)
Figure 2. Asymptotic Loop Response of Peak Current-Mode Regulator
If COUT is large, or exhibits a lossy equivalent series
resistance (large ESR), the circuit’s second zero may
come into play around the crossover frequency (fCO =
ωCO/2π). In this case, a third pole may be induced by a
second (optional) small compensation capacitor (CCC),
connected from COMP to SGND.
The loop response’s fourth asymptote (in bold, Figure
2) is the one of interest in establishing the desired
crossover frequency (and determining the compensation component values). A lower crossover frequency
provides for stable closed-loop operation at the
expense of a slower load and line transient response.
Increasing the crossover frequency improves the transient response at the (potential) cost of system instability. A standard rule of thumb sets the crossover
frequency ≤ 1/10 of the switching frequency (for the
MAX15041, this is approximately 35kHz for the 350kHz
fixed switching frequency).
First, select the passive and active power components
that meet the application’s requirements. Then, choose
the small-signal compensation components to achieve
14
the desired closed-loop frequency response and phase
margin as outlined in the Closing the Loop: Designing
the Compensation Circuitry section.
Closing the Loop: Designing the
Compensation Circuitry
1) Select the desired crossover frequency. Choose fCO
equal to 1/10th of fSW, or fCO ≈ 35kHz.
2) Select RC using the transfer-loop’s fourth asymptote
gain (assuming fCO > fP1, fP2, and fZ1 and setting
the overall loop gain to unity) as follows:
1=
×
VFB
× gMV × RC × GMOD × RLOAD
VOUT
1
2π × fCO × COUT × (ESR + RLOAD )
therefore:
2π × fCO × COUT × (ESR + RLOAD )
V
RC = OUT ×
VFB
gMV × GMOD × RLOAD
______________________________________________________________________________________
Low-Cost, 3A, 4.5V to 28V Input, 350kHz, PWM
Step-Down DC-DC Regulator with Internal Switches
V
2π × fCO × COUT
RC = OUT ×
VFB
gMV × GMOD
where VFB is equal to 0.606V.
3) Select C C . C C is determined by selecting the
desired first system zero, fZ1, based on the desired
phase margin. Typically, setting fZ1 below 1/5th of
fCO provides sufficient phase margin.
fZ1 =
f
1
≤ CO
2π × CCRC
5
therefore:
CC ≥
5
2π × fCO × RC
4) If the ESR output zero is located at less than one-half
the switching frequency use the (optional) secondary compensation capacitor, CCC, to cancel it,
as follows:
1
1
= fP3 = fZ2 =
2π × CCCRC
2π × COUTESR
therefore:
CCC =
COUT × ESR
RC
If the ESR zero exceeds 1/2 the switching frequency,
use the following equation:
fP3 =
f
1
= SW
2π × CCCRC
2
therefore:
CCC =
2
2π × fSW × RC
this third-pole placement is well beyond the desired
crossover frequency, minimizing its interaction with the
system loop response at crossover. If CCC is smaller than
10pF, it can be neglected in these calculations.
Setting the Soft-Start Time
The soft-start feature ramps up the output voltage slowly, reducing input inrush current during startup. Size the
CSS capacitor to achieve the desired soft-start time tSS
using:
I ×t
CSS = SS SS
VFB
ISS, the soft-start current, is 5µA (typ) and VFB, the output feedback voltage threshold, is 0.606V (typ). When
using large COUT capacitance values, the high-side
current limit may trigger during the soft-start period. To
ensure the correct soft-start time, tSS, choose CSS large
enough to satisfy:
CSS >> COUT ×
VOUT × ISS
(IHSCL _ MIN − IOUT ) × VFB
IHSCL_MIN is the minimum high-side switch, currentlimit value.
Power Dissipation
The MAX15041 is available in a thermally enhanced
TQFN package and can dissipate up to 1.666W at TA =
+70°C. The exposed pad should be connected to
SGND externally, preferably soldered to a large ground
plane to maximize thermal performance. When the die
temperature exceeds +155°C, The thermal-shutdown
protection is activated (see the Thermal-Shutdown
Protection section).
Layout Procedure
Careful PCB layout is critical to achieve clean and stable operation. It is highly recommended to duplicate
the MAX15041 evaluation kit layout for optimum performance. If deviation is necessary, follow these guidelines for good PCB layout:
1) Connect input and output capacitors to the power
ground plane; connect all other capacitors to the
signal ground plane.
The downside of CCC is that it detracts from the overall
system phase margin. Care should be taken to guarantee
______________________________________________________________________________________
15
MAX15041
For RLOAD much greater than ESR, the equation can be
further simplified as follows:
MAX15041
Low-Cost, 3A, 4.5V to 28V Input, 350kHz, PWM
Step-Down DC-DC Regulator with Internal Switches
2) Place capacitors on VDD, IN, and SS as close as
possible to the IC and the corresponding pin using
direct traces. Keep the power ground plane (connected to PGND) and signal ground plane (connected to SGND) separate. PGND and SGND connect at
only one common point near the input bypass
capacitor return terminal.
4) Connect IN, LX, and PGND separately to a large
copper area to help cool the IC to further improve
efficiency.
5) Ensure all feedback connections are short and
direct. Place the feedback resistors and compensation components as close as possible to the IC.
6) Route high-speed switching nodes (such as LX and
BST) away from sensitive analog areas (such as FB
and COMP).
3) Keep the high-current paths as short and wide as
possible. Keep the path of switching current short
and minimize the loop area formed by LX, the output
capacitors, and the input capacitors.
D
INPUT
4.5V TO 28V
RBST
47Ω
IN
BST
CIN
47µF
VDD
RPU
10kΩ
CBST
10nF
MAX15041
EN
L
4.7µH
OUTPUT = 3.3V
LX
COUT
22µF
CVDD
1µF
R1
45.3kΩ
1%
PGND
PGOOD
FB
PGOOD
SS
COMP
I.C.
SGND
CSS
0.01µF
R2
10.0kΩ
1%
RC
1.8kΩ
CCC
100pF
CC
12nF
Figure 3. Typical Operating Circuit (4.5V to 28V Input Buck Converter)
Table 1. Typical Component Values for Common Output-Voltage Settings
16
VOUT (V)
L (µH)
CC (nF)
RC (kΩ)
5.0
3.3
4.7
8
2.70
4.7
12
1.80
2.5
3.3
22
1.50
1.8
2.2
33
1.00
1.2
2.2
47
0.68
R1 and R2
Select R2 so that:
5kΩ ≤ R2 ≤ 50kΩ
Calculate R1 using the equation in the
Setting the Output Voltage section.
______________________________________________________________________________________
Low-Cost, 3A, 4.5V to 28V Input, 350kHz, PWM
Step-Down DC-DC Regulator with Internal Switches
PROCESS: BiCMOS
For the latest package outline information and land patterns, go
to www.maxim-ic.com/packages. Note that a “+”, “#”, or “-” in
the package code indicates RoHS status only. Package drawings may show a different suffix character, but the drawing pertains to the package regardless of RoHS status.
PACKAGE
TYPE
PACKAGE
CODE
OUTLINE NO.
LAND
PATTERN NO.
16 TQFN-EP
T1633+4
21-0136
90-0031
______________________________________________________________________________________
17
MAX15041
Package Information
Chip Information
MAX15041
Low-Cost, 3A, 4.5V to 28V Input, 350kHz, PWM
Step-Down DC-DC Regulator with Internal Switches
Revision History
REVISION
NUMBER
REVISION
DATE
0
7/09
Initial release
1
3/10
Revised General Description, Absolute Maximum Ratings, Applications
Information, Figures 2 and 3.
2
9/10
Update Electrical Characteristics and Package Information
DESCRIPTION
PAGES
CHANGED
—
1, 2, 3, 7, 10–13,
15, 16
2, 17, 18
Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are
implied. Maxim reserves the right to change the circuitry and specifications without notice at any time.
18 ____________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600
© 2010 Maxim Integrated Products
Maxim is a registered trademark of Maxim Integrated Products, Inc.