MAXIM MAX5974CETE

19-5331; Rev 2; 6/11
TION KIT
EVALUA BLE
IL
AVA A
Active-Clamped, Spread-Spectrum,
Current-Mode PWM Controllers
Features
The MAX5974_ provide control for wide-input-voltage,
active-clamped, current-mode PWM, forward converters
in Power-over-Ethernet (PoE) powered device (PD) applications. The MAX5974A/MAX5974C are well-suited for
universal or telecom input range, while the MAX5974B/
MAX5974D also accommodate low input voltage down
to 10.5V.
S Peak Current-Mode Control, Active-Clamped
Forward PWM Controller
S Regulation Without Optocoupler (MAX5974A/
MAX5974B)
S Internal 1% Error Amplifier
S 100kHz to 600kHz Programmable Q8% Switching
Frequency, Synchronization Up to 1.2MHz
S Programmable Frequency Dithering for Low-EMI,
Spread-Spectrum Operation
S Programmable Dead Time, PWM Soft-Start,
Current Slope Compensation
S Programmable Feed-Forward Maximum DutyCycle Clamp, 80% Maximum Limit
S Frequency Foldback for High-Efficiency LightLoad Operation
S Internal Bootstrap UVLO with Large Hysteresis
S 100µA (typ) Startup Supply Current
S Fast Cycle-by-Cycle Peak Current-Limit, 35ns
Typical Propagation Delay
S 115ns Current-Sense Internal Leading-Edge
Blanking
S Output Short-Circuit Protection with Hiccup Mode
S Reverse Current Limit to Prevent Transformer
Saturation Due to Reverse Current
S Internal 18V Zener Clamp on Supply Input
S 3mm x 3mm, Lead-Free, 16-Pin TQFN-EP
The devices include several features to enhance supply
efficiency. The AUX driver recycles magnetizing current instead of wasting it in a dissipative clamp circuit.
Programmable dead time between the AUX and main
driver allows for zero-voltage switching (ZVS). Under lightload conditions, the devices reduce the switching frequency (frequency foldback) to reduce switching losses.
The MAX5974A/MAX5974B feature unique circuitry to
achieve output regulation without using an optocoupler,
while the MAX5974C/MAX5974D utilize the traditional
optocoupler feedback method. An internal error amplifier
with a 1% reference is very useful in nonisolated design,
eliminating the need for an external shunt regulator.
The devices feature a unique feed-forward maximum
duty-cycle clamp that makes the maximum clamp voltage during transient conditions independent of the line
voltage, allowing the use of a power MOSFET with lower
breakdown voltage. The programmable frequency dithering feature provides low-EMI, spread-spectrum operation.
The MAX5974_ are available in 16-pin TQFN-EP packages and are rated for operation over the -40°C to +85°C
temperature range.
Applications
PoE IEEE® 802.3af/at Powered Devices
High-Power PD (Beyond the 802.3af/at Standard)
Active-Clamped Forward DC-DC Converters
IP Phones
Wireless Access Nodes
Security Cameras
Ordering Information/Selector Guide
UVLO THRESHOLD (V)
FEEDBACK MODE
MAX5974AETE+
PART
TOP MARK
+AHY
16 TQFN-EP*
PIN-PACKAGE
16
Sample/Hold
MAX5974BETE+
+AHZ
16 TQFN-EP*
8.4
Sample/Hold
MAX5974CETE+
+AIA
16 TQFN-EP*
16
Continuously Connected
MAX5974DETE+
+AIB
16 TQFN-EP*
8.4
Continuously Connected
Note: All devices are specified over the -40°C to +85°C operating temperature range.
+Denotes a lead(Pb)-free/RoHS-compliant package.
*EP = Exposed pad.
IEEE is a registered service mark of the Institute of Electrical and Electronics Engineers, Inc.
________________________________________________________________ Maxim Integrated Products 1
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.
MAX5974A/MAX5974B/MAX5974C/MAX5974D
General Description
MAX5974A/MAX5974B/MAX5974C/MAX5974D
Active-Clamped, Spread-Spectrum,
Current-Mode PWM Controllers
ABSOLUTE MAXIMUM RATINGS
IN to GND (VEN = 0V)............................................-0.3V to +26V
EN, NDRV, AUXDRV to GND......................-0.3V to (VIN + 0.3V)
RT, DT, FFB, COMP, SS, DCLMP, DITHER/SYNC
to GND..................................................................-0.3V to +6V
FB to GND (MAX5974A/MAX5974B only)...................-6V to +6V
FB to GND (MAX5974C/MAX5974D only)...............-0.3V to +6V
CS, CSSC to GND....................................................-0.8V to +6V
PGND to GND.......................................................-0.3V to +0.3V
Maximum Input/Output Current (continuous)
IN, NDRV, AUXDRV.......................................................100mA
NDRV, AUXDRV (pulsed for less than 100ns)................... Q1A
Continuous Power Dissipation (TA = +70NC) (Note 1)
16-Pin TQFN (derate 20.8mW/NC above +70NC)........1666mW
Operating Temperature Range........................... -40NC to +85NC
Maximum Junction Temperature......................................+150NC
Storage Temperature Range............................. -65NC to +150NC
Lead Temperature (soldering, 10s).................................+300NC
Soldering Temperature (reflow).......................................+260NC
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.
PACKAGE THERMAL CHARACTERISTICS (Note 1)
Junction-to-Ambient Thermal Resistance (BJA)...............48NC/W
Junction-to-Case Thermal Resistance (BJC)......................7NC/W
Note 1: 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.
ELECTRICAL CHARACTERISTICS
(VIN = 12V (for MAX5974A/MAX5974C, bring VIN up to 17V for startup), VCS = VCSSC = VDITHER/SYNC = VFB = VFFB = VDCLMP =
VGND, VEN = +2V, NDRV = AUXDRV = SS = COMP = unconnected, RRT = 34.8kI, RDT = 25kI, CIN = 1FF, TA = -40NC to +85NC,
unless otherwise noted. Typical values are at TA = +25NC.) (Note 2)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
MAX5974A/
MAX5974C
15.4
16
16.5
MAX5974B/
MAX5974D
8
8.4
8.85
6.65
7
7.35
V
17
18.5
20
V
VIN = +15V (for MAX5974A/
MAX5974C);
VIN = +7.5V (for MAX5974B/MAX5974D),
when in bootstrap UVLO
100
150
FA
IC
VIN = +12V
1.8
3
mA
VENR
VEN rising
1.17
1.215
1.26
VENF
VEN falling
1.09
1.14
1.19
UNDERVOLTAGE LOCKOUT/STARTUP (IN)
Bootstrap UVLO Wakeup Level
Bootstrap UVLO Shutdown
Level
IN Clamp Voltage
IN Supply Current in
Undervoltage Lockout
IN Supply Current After Startup
VINUVR
VINUVF
VIN_CLAMP
ISTART
VIN rising
VIN falling
IIN = 2mA (sinking)
V
ENABLE (EN)
Enable Threshold
Input Current
IEN
1
V
FA
OSCILLATOR (RT)
RT Bias Voltage
VRT
NDRV Switching Frequency
Range
fSW
2
1.23
100
V
600
kHz
Active-Clamped, Spread-Spectrum,
Current-Mode PWM Controllers
(VIN = 12V (for MAX5974A/MAX5974C, bring VIN up to 17V for startup), VCS = VCSSC = VDITHER/SYNC = VFB = VFFB = VDCLMP =
VGND, VEN = +2V, NDRV = AUXDRV = SS = COMP = unconnected, RRT = 34.8kI, RDT = 25kI, CIN = 1FF, TA = -40NC to +85NC,
unless otherwise noted. Typical values are at TA = +25NC.) (Note 2)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
NDRV Switching Frequency
Accuracy
Maximum Duty Cycle
-8
DMAX
fSW = 250kHz
79
80
+8
%
82
%
SYNCHRONIZATION (SYNC)
Synchronization Logic-High
Input
VIH-SYNC
2.91
fSYNCIN
1.1 x
fSW
Synchronization Pulse Width
Synchronization Frequency
Range
V
50
Maximum Duty Cycle During
Synchronization
ns
2x
fSW
DMAX x fSYNC/
fSW
kHz
%
DITHERING RAMP GENERATOR (DITHER)
Charging Current
VDITHER = 0V
45
50
55
FA
Discharging Current
VDITHER = 2.2V
43
50
57
FA
Ramp’s High Trip Point
2
V
Ramp’s Low Trip Point
0.4
V
SOFT-START AND RESTART (SS)
Charging Current
ISS-CH
ISS-D
Discharging Current
Discharge Threshold to Disable
Hiccup and Restart
Minimum Restart Time During
Hiccup Mode
Normal Operating High Voltage
Duty-Cycle Control Range
ISS-DH
9.5
10
10.5
FA
VSS = 2V, normal shutdown
0.65
1.34
2
mA
(VEN < VENF or VIN < VINUVF),
VSS = 2V, hiccup mode discharge for
tRSTRT (Note 3)
1.6
2
2.4
FA
VSS-DTH
0.15
V
tRSTRT-MIN
1024
Clock
Cycles
VSS-HI
VSS-DMAX
5
DMAX (typ) = (VSS-DMAX/2.43V)
0
V
2
V
nA
DUTY-CYCLE CLAMP (DCLMP)
DCLMP Input Current
IDCLMP
VDCLMP = 0 to 5V
VDCLMP = 0.5V
Duty-Cycle Control Range
VDCLMP-R
DMAX (typ) =
1 - (VDCLMP/2.43V)
-100
0
+100
73
75.4
77.5
VDCLMP = 1V
54
56
58
VDCLMP = 2V
14.7
16.5
18.3
%
NDRV DRIVER
Pulldown Impedance
RNDRV-N
INDRV (sinking) = 100mA
1.9
3.4
I
Pullup Impedance
RNDRV-P
INDRV (sourcing) = 50mA
4.7
8.3
I
Peak Sink Current
1
Peak Source Current
A
0.65
A
Fall Time
tNDRV-F
CNDRV = 1nF
14
ns
Rise Time
tNDRV-R
CNDRV = 1nF
27
ns
3
MAX5974A/MAX5974B/MAX5974C/MAX5974D
ELECTRICAL CHARACTERISTICS (continued)
MAX5974A/MAX5974B/MAX5974C/MAX5974D
Active-Clamped, Spread-Spectrum,
Current-Mode PWM Controllers
ELECTRICAL CHARACTERISTICS (continued)
(VIN = 12V (for MAX5974A/MAX5974C, bring VIN up to 17V for startup), VCS = VCSSC = VDITHER/SYNC = VFB = VFFB = VDCLMP =
VGND, VEN = +2V, NDRV = AUXDRV = SS = COMP = unconnected, RRT = 34.8kI, RDT = 25kI, CIN = 1FF, TA = -40NC to +85NC,
unless otherwise noted. Typical values are at TA = +25NC.) (Note 2)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
AUXDRV DRIVER
Pulldown Impedance
RAUX-N
IAUXDRV (sinking) = 50mA
4.3
7.7
I
Pullup Impedance
RAUX-P
IAUXDRV (sourcing) = 25mA
10.6
18.9
I
Peak Sink Current
0.5
Peak Source Current
0.3
A
A
Fall Time
tAUX-F
CAUXDRV = 1nF
24
ns
Rise Time
tAUX-R
CAUXDRV = 1nF
45
ns
1.215
V
DEAD-TIME PROGRAMMING (DT)
DT Bias Voltage
VDT
NDRV to AUXDRV Delay
(Dead Time)
tDT
From NDRV falling
to AUXDRV falling
RDT = 10kI
From AUXDRV rising
to NDRV rising
RDT = 10kI
RDT = 100kI
RDT = 100kI
40
410
ns
300
350
310
360
420
375
393
410
mV
-118
-100
-88
mV
40
ns
CURRENT-LIMIT COMPARATOR (CS)
Cycle-by-Cycle Peak
Current-Limit Threshold
VCS-PEAK
Cycle-by-Cycle Reverse
Current-Limit Threshold
VCS-REV
Current-Sense Blanking Time
for Reverse Current Limit
tCS-BLANKREV
Number of Consecutive Peak
Current-Limit Events to Hiccup
NHICCUP
Current-Sense Leading-Edge
Blanking Time
tCS-BLANK
Propagation Delay from
Comparator Input to NDRV
tPDCS
Minimum On-Time
Turns AUXDRV off for the remaining
cycle if reverse current limit is exceeded
From AUXDRV falling edge
115
ns
8
Events From NDRV rising edge
115
ns
From CS rising (10mV overdrive) to
NDRV falling (excluding leading-edge
blanking)
35
ns
tON-MIN
100
150
200
ns
47
52
58
FA
SLOPE COMPENSATION (CSSC)
Slope Compensation Current
Ramp Height
Current ramp’s peak added to CSSC
input per switching cycle
PWM COMPARATOR
Comparator Offset Voltage
VPWM-OS
VCOMP - VCSSC
1.35
1.7
2
V
Current-Sense Gain
ACS-PWM
DVCOMP/DVCSSC (Note 4)
3.1
3.33
3.6
V/V
Current-Sense Leading-Edge
Blanking Time
Comparator Propagation Delay
4
tCSSC-BLANK
tPWM
From NDRV rising edge
115
ns
Change in VCSSC = 10mV (including
internal leading-edge blanking)
150
ns
Active-Clamped, Spread-Spectrum,
Current-Mode PWM Controllers
(VIN = 12V (for MAX5974A/MAX5974C, bring VIN up to 17V for startup), VCS = VCSSC = VDITHER/SYNC = VFB = VFFB = VDCLMP =
VGND, VEN = +2V, NDRV = AUXDRV = SS = COMP = unconnected, RRT = 34.8kI, RDT = 25kI, CIN = 1FF, TA = -40NC to +85NC,
unless otherwise noted. Typical values are at TA = +25NC.) (Note 2)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
MAX5974A/
MAX5974B
1.5
1.52
1.54
MAX5974C/
MAX5974D
1.202
1.215
1.227
MAX5974A/
MAX5974B
-250
+250
MAX5974C/
MAX5974D
-500
+100
UNITS
ERROR AMPLIFIER
FB Reference Voltage
FB Input Bias Current
Voltage Gain
Transconductance
Transconductance Bandwidth
VREF
IFB
VFB when ICOMP = 0,
VCOMP = 2.5V
VFB = 0 to 1.75V
AEAMP
nA
gM
BW
V Open loop (typical gain
= 1) -3dB frequency
80
dB
MAX5974A/
MAX5974B
1.8
2.55
3.2
MAX5974C/
MAX5974D
1.8
2.66
3.5
mS
MAX5974A/
MAX5974B
2
MAX5974C/
MAX5974D
30
MHz
Source Current
VFB = 1V, VCOMP = 2.5V
300
375
455
FA
Sink Current
VFB = 1.75V, VCOMP = 1V
300
375
455
FA
FREQUENCY FOLDBACK (FFB)
VCSAVG-to-FFB Comparator
Gain
FFB Bias Current
NDRV Switching Frequency
During Foldback
IFFB
fSW-FB
10
VFFB = 0V, VCS = 0V (not in FFB mode)
26
30
fSW/2
V/V
33
FA
kHz Note 2: All devices are 100% production tested at TA = +25NC. Limits over temperature are guaranteed by design.
Note 3: See the Output Short-Circuit Protection with Hiccup Mode section.
Note 4: The parameter is measured at the trip point of latch with VFB = 0V. Gain is defined as DVCOMP/DVCSSC for 0.15V <
DVCSSC < 0.25V.
5
MAX5974A/MAX5974B/MAX5974C/MAX5974D
ELECTRICAL CHARACTERISTICS (continued)
Typical Operating Characteristics
(VIN = 12V (for MAX5974A/MAX5974C, bring VIN up to 17V for startup), VCS = VCSSC = VDITHER/SYNC = VFB = VFFB = VDCLMP =
VGND, VEN = 2V, NDRV = AUXDRV = SS = COMP = unconnected, RRT = 34.8kI, RDT = 25kI, unless otherwise noted.)
IN UVLO WAKE-UP LEVEL
vs. TEMPERATURE
IN UVLO WAKE-UP LEVEL
vs. TEMPERATURE
16.0
15.9
8.4
8.3
8.2
8.1
15.8
8.0
15.7
-15
10
35
60
-15
-40
85
10
35
60
7.2
7.1
7.0
6.9
6.8
85
-40
-15
60
TEMPERATURE (°C)
EN RISING THRESHOLD
vs. TEMPERATURE
EN FALLING THRESHOLD
vs. TEMEPRATURE
UVLO SHUTDOWN CURRENT
vs. TEMPERATURE
1.214
1.148
1.147
1.146
1.145
120
MAX5974A/MAX5974C
100
80
1.144
MAX5974B/MAX5974D
1.143
1.210
60
1.142
-15
10
35
60
85
-15
-40
10
35
60
-40
85
-15
10
35
60
TEMPERATURE (°C)
SUPPLY CURRENT vs. SUPPLY VOLTAGE
(MAX5974A/MAX5974C)
SUPPLY CURRENT vs. SUPPLY VOLTAGE
(MAX5974B/MAX5974D)
SUPPLY CURRENT
vs. SWITCHING FREQUENCY
100
1000
100
TA = -40°C
10
TA = -40°C
10
0
2
4
6
8
10 12 14 16 18 20
TEMPERATURE (°C)
0
2
4
6
8
10 12 14 16 18 20
TEMPERATURE (°C)
2.4
85
MAX5974A/B/C/D toc09
TA = +85°C
2.0
SUPPLY CURRENT (mA)
1000
10,000
SUPPLY CURRENT (µA)
TA = +85°C
MAX5974A/B/C/D toc08
TEMPERATURE (°C)
MAX5974A/B/C/D toc07
TEMPERATURE (°C)
10,000
85
MAX5974A/B/C/D toc06
1.149
140
UVLO CURRENT (µA)
1.216
1.150
MAX5974A/B/C/D toc05
MAX5974A/B/C/D toc04
1.218
1.212
6
35
TEMPERATURE (°C)
1.220
-40
10
TEMPERATURE (°C)
EN FALLING THRESHOLD (V)
-40
EN RISING THRESHOLD (V)
8.5
7.3
MAX5974A/B/C/D toc03
16.1
MAX5974B/MAX5974D
IN UVLO SHUTDOWN LEVEL
16.2
8.6
IN UVLO SHUTDOWN LEVEL
vs. TEMPERATURE
MAX5974A/B/C/D toc02
MAX5974A/MAX5974C
IN UVLO WAKE-UP LEVEL (V)
MAX5974A/B/C/D toc01
IN UVLO WAKE-UP LEVEL (V)
16.3
SUPPLY CURRENT (µA)
MAX5974A/MAX5974B/MAX5974C/MAX5974D
Active-Clamped, Spread-Spectrum,
Current-Mode PWM Controllers
1.6
1.2
0.8
0.4
0
0
100 200 300 400 500 600 700 800
SWITCHING FREQUENCY (kHz)
Active-Clamped, Spread-Spectrum,
Current-Mode PWM Controllers
SWITCHING FREQUENCY
vs. RRT VALUE
10.03
10.02
10.01
10.00
9.99
-15
10
35
60
248
247
246
10
85
244
100
-40
35
60
FREQUENCY DITHERING
vs. RDITHER
MAXIMUM DUTY CYCLE
vs. SWITCHING FREQUENCY
MAXIMUM DUTY CYCLE
vs. TEMPERATURE
4
2
81
80
79
78
77
80.9
76
400
500
600
700
800
900
80.7
80.6
80.5
80.4
80.2
0
1000
80.8
80.3
75
0
100 200 300 400 500 600 700 800
-40
-15
10
35
60
SWITCHING FREQUENCY (kHz)
TEMPERATURE (°C)
MAXIMUM DUTY CYCLE
vs. SYNC FREQUENCY
MAXIMUM DUTY CYCLE
vs. VSS
MAXIMUM DUTY CYCLE
vs. VDCLMP
25
20
15
10
80
70
60
50
40
30
20
5
10
0
0
300
350
400
SYNC FREQUENCY (kHz)
450
500
100
85
MAX5974A/B/C/D toc18
90
90
MAXIMUM DUTY CYCLE (%)
30
MAX5974A/B/C/D toc17
35
100
MAXIMUM DUTY CYCLE (%)
MAX5974A/B/C/D toc16
RDITHER (kΩ)
VSS = 0.5V
85
MAX5974A/B/C/D toc15
MAX5974A/B/C/D toc14
82
81.0
MAXIMUM DUTY CYCLE (%)
6
83
MAXIMUM DUTY CYCLE (%)
MAX5974A/B/C/D toc13
8
250
10
TEMPERATURE (°C)
10
300
-15
RRT VALUE (kΩ)
12
40
249
TEMPERATURE (°C)
14
45
250
245
10
-40
FREQUENCY DITHERING (%)
251
9.98
9.97
MAXIMUM DUTY CYCLE (%)
100
252
MAX5974A/B/C/D toc12
10.04
MAX5974A/B/C/D toc11
10.05
1000
SWITCHING FREQUENCY (kHz)
MAX5974A/B/C/D toc10
SOFT-START CHARGING CURRENT (µA)
10.06
SWITCHING FREQUENCY
vs. TEMPERATURE
SWITCHING FREQUENCY (kHz)
SOFT-START CHARGING CURRENT
vs. TEMPERATURE
80
70
60
50
40
30
20
10
0
0
0.5
1.0
1.5
VSS (V)
2.0
2.5
0
0.5
1.0
1.5
2.0
2.5
VDCLMP (V)
7
MAX5974A/MAX5974B/MAX5974C/MAX5974D
Typical Operating Characteristics (continued)
(VIN = 12V (for MAX5974A/MAX5974C, bring VIN up to 17V for startup), VCS = VCSSC = VDITHER/SYNC = VFB = VFFB = VDCLMP =
VGND, VEN = 2V, NDRV = AUXDRV = SS = COMP = unconnected, RRT = 34.8kI, RDT = 25kI, unless otherwise noted.)
Typical Operating Characteristics (continued)
(VIN = 12V (for MAX5974A/MAX5974C, bring VIN up to 17V for startup), VCS = VCSSC = VDITHER/SYNC = VFB = VFFB = VDCLMP =
VGND, VEN = 2V, NDRV = AUXDRV = SS = COMP = unconnected, RRT = 34.8kI, RDT = 25kI, unless otherwise noted.)
250
200
150
94
92
100
50
90
0
88
10
20
30
40
50
60
70
80
396
395
394
393
392
391
390
389
388
-40
90 100
397
-15
10
35
60
85
-40
110
-15
10
35
60
RDT VALUE (kΩ)
TEMPERATURE (°C)
TEMPERATURE (°C)
REVERSE CURRENT-LIMIT THRESHOLD
vs. TEMPERATURE
SLOPE COMPENSATION CURRENT
vs. TEMPERATURE
NDRV MINIMUM ON-TIME
vs. TEMPERATURE
-101
-102
-103
-104
-105
-106
-107
-15
10
35
60
52.5
52.0
51.5
51.0
160
155
150
140
-40
-15
10
35
60
85
-40
-15
10
35
TEMPERATURE (°C)
TEMPERATURE (°C)
CURRENT-SENSE GAIN
vs. TEMPERATURE
FEEDBACK VOLTAGE
vs. TEMPERATURE
FEEDBACK VOLTAGE
vs. TEMPERATURE
3.37
3.36
3.35
3.34
3.33
1.219
1.218
1.217
1.216
1.215
1.214
1.213
3.32
1.212
3.31
1.211
3.30
MAX5974C/MAX5974D
10
35
TEMPERATURE (°C)
60
85
85
60
85
1.522
1.521
1.520
1.519
1.518
1.517
1.210
-15
60
MAX5974A/B/C/D toc27
3.38
1.220
FEEDBACK VOLTAGE (V)
MAX5974A/B/C/D toc25
3.39
MAX5974A/B/C/D toc26
TEMPERATURE (°C)
3.40
-40
165
145
50.5
50.0
85
FEEDBACK VOLTAGE (V)
-40
53.0
85
MAX5974A/B/C/D toc24
-100
53.5
170
NDRV MINIMUM ON-TIME (ns)
-99
54.0
MAX5974A/B/C/D toc23
-98
SLOPE COMPENSATION CURRENT (mA)
MAX5974A/B/C/D toc22
-97
REVERSE CURRENT-LIMIT THRESHOLD (mV)
96
MAX5974A/B/C/D toc21
98
398
PEAK CURRENT-LIMIT THRESHOLD (mV)
100
DEAD TIME (ns)
300
MAX5974A/B/C/D toc20
350
DEAD TIME (ns)
102
MAX5974A/B/C/D toc19
400
8
PEAK CURRENT-LIMIT THRESHOLD
vs. TEMPERATURE
DEAD TIME vs. TEMPERATURE
DEAD TIME vs. RDT VALUE
CURRENT-SENSE GAIN (V/V)
MAX5974A/MAX5974B/MAX5974C/MAX5974D
Active-Clamped, Spread-Spectrum,
Current-Mode PWM Controllers
-40
-15
10
35
TEMPERATURE (°C)
60
85
1.516
-40
-15
10
35
TEMPERATURE (°C)
Active-Clamped, Spread-Spectrum,
Current-Mode PWM Controllers
TRANSCONDUCTANCE HISTOGRAM
(MAX5974A/MAX5974B)
2.6
20
2.5
2.4
MAX5974A/MAX5974B
15
20
N (%)
2.7
25
MAX5974A/B/C/D toc29
MAX5974C/MAX5974D
N (%)
TRANSCONDUCTANCE (mS)
2.9
2.8
25
MAX5974A/B/C/D toc28
3.0
TRANSCONDUCTANCE HISTOGRAM
(MAX5974C/MAX5974D)
MAX5974A/B/C/D toc30
TRANSCONDUCTANCE
vs. TEMPERATURE
15
10
10
5
5
2.3
2.2
2.1
2.0
-40
-15
10
35
60
85
0
0
2.44 2.46 2.48 2.50 2.52 2.54 2.56 2.58 2.60 2.62 2.64
2.56 2.58 2.60 2.62 2.64 2.66 2.68 2.70 2.72 2.74 2.76
TRANSCONDUCTANCE (mS)
TRANSCONDUCTANCE (mS)
TEMPERATURE (°C)
SHUTDOWN RESPONSE
ENABLE RESPONSE
MAX5974A/B/C/D toc31
MAX5974A/B/C/D toc32
VEN
5V/div
VEN
5V/div
VNDRV
10V/div
VNDRV
10V/div
VAUXDRV
10V/div
VAUXDRV
10V/div
VOUT
5V/div
100µs/div
200µs/div
VSS RAMP RESPONSE
VDCLMP RAMP RESPONSE
MAX5974A/B/C/D toc33
10µs/div
VOUT
5V/div
MAX5974A/B/C/D toc34
VSS
2V/div
VDCLMP
2V/div
VNDRV
10V/div
VNDRV
10V/div
VAUXDRV
10V/div
VAUXDRV
10V/div
10µs/div
9
MAX5974A/MAX5974B/MAX5974C/MAX5974D
Typical Operating Characteristics (continued)
(VIN = 12V (for MAX5974A/MAX5974C, bring VIN up to 17V for startup), VCS = VCSSC = VDITHER/SYNC = VFB = VFFB = VDCLMP =
VGND, VEN = 2V, NDRV = AUXDRV = SS = COMP = unconnected, RRT = 34.8kI, RDT = 25kI, unless otherwise noted.)
MAX5974A/MAX5974B/MAX5974C/MAX5974D
Active-Clamped, Spread-Spectrum,
Current-Mode PWM Controllers
Typical Operating Characteristics (continued)
(VIN = 12V (for MAX5974A/MAX5974C, bring VIN up to 17V for startup), VCS = VCSSC = VDITHER/SYNC = VFB = VFFB = VDCLMP =
VGND, VEN = 2V, NDRV = AUXDRV = SS = COMP = unconnected, RRT = 34.8kI, RDT = 25kI, unless otherwise noted.)
NDRV 10% TO 90% RISE TIME
NDRV 90% TO 10% FALL TIME
MAX5974A/B/C/D toc35
AUXDRV 10% TO 90% RISE TIME
MAX5974A/B/C/D toc36
MAX5974A/B/C/D toc37
0ns
27.6ns
45.6ns
VNDRV
2V/div
VNDRV
2V/div
13.8ns
0ns
10ns/div
VAUXDRV
2V/div
0ns
10ns/div
10ns/div
AUXDRV 90% TO 10% FALL TIME
PEAK NDRV CURRENT
MAX5974A/B/C/D toc38
MAX5974A/B/C/D toc39
PEAK SOURCE CURRENT
0ns
VAUXDRV
2V/div
INDRV
0.5A/div
21ns
PEAK SINK CURRENT
10ns/div
200ns/div
PEAK AUXDRV CURRENT
SHORT-CURRENT BEHAVIOR
MAX5974A/B/C/D toc40
MAX5974A/B/C/D toc41
15V
VIN
5V/div
PEAK SOURCE
CURRENT
5V
IAUXDRV
0.2A/div
VNDRV
10V/div
VCS
500mV/div
PEAK SINK CURRENT
400ns/div
10
40ms/div
Active-Clamped, Spread-Spectrum,
Current-Mode PWM Controllers
AUXDRV
NDRV
PGND
CS
TOP VIEW
12
11
10
9
IN 13
MAX5974A
MAX5974B
MAX5974C
MAX5974D
EN 14
DCLMP 15
EP
2
3
4
FFB
DT
1
RT
+
DITHER/
SYNC
SS 16
8
CSSC
7
GND
6
FB
5
COMP
THIN QFN
Pin Description
PIN
NAME
FUNCTION
1
DT
Dead-Time Programming Resistor Connection. Connect resistor RDT from DT to GND to set the
desired dead time between the NDRV and AUXDRV signals. See the Dead Time section to calculate
the resistor value for a particular dead time.
2
DITHER/
SYNC
Frequency Dithering Programming or Synchronization Connection. For spread-spectrum frequency
operation, connect a capacitor from DITHER to GND and a resistor from DITHER to RT. To
synchronize the internal oscillator to the externally applied frequency, connect DITHER/SYNC to the
synchronization pulse.
3
RT
Switching Frequency Programming Resistor Connection. Connect resistor RRT from RT to GND to
set the PWM switching frequency. See the Oscillator/Switching Frequency section to calculate the
resistor value for the desired oscillator frequency.
4
FFB
Frequency Foldback Threshold Programming Input. Connect a resistor from FFB to GND to set the
output average current threshold below which the converter folds back the switching frequency to
1/2 of its original value. Connect to GND to disable frequency foldback.
5
COMP
Transconductance Amplifier Output and PWM Comparator Input. COMP is level shifted down and
connected to the inverting input of the PWM comparator.
11
MAX5974A/MAX5974B/MAX5974C/MAX5974D
Pin Configuration
Active-Clamped, Spread-Spectrum,
Current-Mode PWM Controllers
MAX5974A/MAX5974B/MAX5974C/MAX5974D
Pin Description (continued)
PIN
12
NAME
FUNCTION
6
FB
7
GND
Transconductance Amplifier Inverting Input
Signal Ground
8
CSSC
Current Sense with Slope Compensation Input. A resistor connected from CSSC to CS programs the
amount of slope compensation. See the Programmable Slope Compensation section.
9
CS
Current-Sense Input. Current-sense connection for average current sense and cycle-by-cycle
current limit. Peak current-limit trip voltage is 400mV and reverse current-limit trip voltage is -100mV.
10
PGND
Power Ground. PGND is the return path for gate-driver switching currents.
11
NDRV
Main Switch Gate-Driver Output
12
AUXDRV
13
IN
Converter Supply Input. IN has wide UVLO hysteresis, enabling the design of efficient power
supplies. See the Enable Input section to determine if an external zener diode is required at IN.
14
EN
Enable Input. The gate drivers are disabled and the device is in a low-power UVLO mode when the
voltage on EN is below VENF. When the voltage on EN is above VENR, the device checks for other
enable conditions. See the Enable Input section for more information about interfacing to EN.
15
DCLMP
Feed-Forward Maximum Duty-Cycle Clamp Programming Input. Connect a resistive divider between
the input supply voltage DCLMP and GND. The voltage at DCLMP sets the maximum duty cycle
(DMAX) of the converter inversely proportional to the input supply voltage, so that the MOSFET
remains protected during line transients.
16
SS
Soft-Start Programming Capacitor Connection. Connect a capacitor from SS to GND to program the
soft-start period. This capacitor also determines hiccup mode current-limit restart time. A resistor
from SS to GND can also be used to set the DMAX below 75%.
—
EP
Exposed Pad. Internally connected to GND. Connect to a large ground plane to maximize thermal
performance. Not intended as an electrical connection point.
pMOS Active Clamp Switch Gate-Driver Output. AUXDRV can also be used to drive a pulse
transformer for synchronous flyback application.
1
3
DT
RT
SYNC
PGND
DRIVER
0.5A/-0.3A
VC
PGND
DRIVER
1A/-0.65A
4
2
7
10
FFB
DITHER/
SYNC
GND
PGND
VB
VB
AUXDRV
NDRV
OSCILLATOR
-50µA
50µA/
90µA
30µA/
15 20% < DMAX < 80%
12
AUXDRV
DCLMP
11
NDRV
FFB COMP
SS
DEAD TIME
DEAD-TIME
CONTROL
2V/400mV
VCSAVG
10X
POK
NDRV
BLANKING
PULSE
REVERSE ILIM LIMIT TURNS
OFF AUX IMMEDIATELY
DRIVER LOGIC
VB
POK
VSS < 150mV
R
S
5V
REGULATOR
MAX5974A
MAX5974B
QCLR
QSET
ENABLE
COUNT 8
EVENTS
THERMAL
SHUTDOWN
PWM
COMP
PEAK ILIM
COMP
1.215V
R1
18V
VB
115ns
BLANKING
115ns
BLANKING
2 x R1
400mV
-100mV
UVLO
2µA
1.52V
SLOPE
COMPENSATION
LOW-POWER UVLO
VINUVR = 16V (MAX5974A)
VINUVR = 8.4V (MAX5974B)
VINUVF = 7V
gM
VB
VB
POK
S/H
2mA
10µA
14 EN
13 IN
6 FB
5 COMP
8 CSSC
9 CS
16 SS
Block Diagrams
13
MAX5974A/MAX5974B/MAX5974C/MAX5974D
VC
HICCUP
LATCH
REVERSE ILIM COMP
VB
Active-Clamped, Spread-Spectrum,
Current-Mode PWM Controllers
14
1
3
DT
RT
SYNC
PGND
DRIVER
0.5A/-0.3A
VC
PGND
DRIVER
1A/-0.65A
4
2
7
10
FFB
DITHER/
SYNC
GND
PGND
VB
VB
AUXDRV
NDRV
OSCILLATOR
-50µA
50µA/
90µA
30µA/
15 20% < DMAX < 80%
12
AUXDRV
DCLMP
11
NDRV
VC
FFB COMP
SS
DEAD TIME
DEAD-TIME
CONTROL
2V/400mV
VCSAVG
10X
POK
NDRV
BLANKING
PULSE
REVERSE ILIM LIMIT TURNS
OFF AUX IMMEDIATELY
DRIVER LOGIC
VB
POK
VSS < 150mV
R
S
5V
REGULATOR
MAX5974C
MAX5974D
QCLR
QSET
ENABLE
COUNT 8
EVENTS
REVERSE ILIM COMP
HICCUP
LATCH
THERMAL
SHUTDOWN
PWM
COMP
PEAK ILIM
COMP
1.215V
R1
18V
VB
115ns
BLANKING
115ns
BLANKING
2 x R1
400mV
-100mV
UVLO
2µA
1.215V
SLOPE
COMPENSATION
LOW-POWER UVLO
VINUVR = 16V (MAX5974C)
VINUVR = 8.4V (MAX5974D)
VINUVF = 7V
gM
VB
VB
POK
VB
2mA
10µA
14 EN
13 IN
6 FB
5 COMP
8 CSSC
9 CS
16 SS
MAX5974A/MAX5974B/MAX5974C/MAX5974D
Active-Clamped, Spread-Spectrum,
Current-Mode PWM Controllers
Block Diagrams (continued)
Active-Clamped, Spread-Spectrum,
Current-Mode PWM Controllers
The MAX5974A/MAX5974B/MAX5974C/MAX5974D are
optimized for controlling a 25W to 50W active-clamped,
self-driven synchronous rectification forward converter
in continuous-conduction mode. The main switch gate
driver (NDRV) and the active-clamped switch driver
(AUXDRV) are sized to optimize efficiency for 25W
design. The features-rich devices are ideal for PoE IEEE
802.3af/at-powered devices.
The MAX5974A/MAX5974C offer a 16V bootstrap UVLO
wake-up level with a 9V wide hysteresis. The low startup
and operating currents allow the use of a smaller storage
capacitor at the input without compromising startup and
hold times. The MAX5974A/MAX5974C are well-suited
for universal input (rectified 85V AC to 265V AC) or telecom (-36V DC to -72V DC) power supplies.
The MAX5974B/MAX5974D have a UVLO rising threshold
of 8.4V and can accommodate for low-input voltage (12V
DC to 24V DC) power sources such as wall adapters.
Power supplies designed with the MAX5974A/MAX5974C
use a high-value startup resistor, RIN, that charges a
reservoir capacitor, CIN (see the Typical Application
Circuits). During this initial period, while the voltage is
less than the internal bootstrap UVLO threshold, the
device typically consumes only 100FA of quiescent current. This low startup current and the large bootstrap
UVLO hysteresis help to minimize the power dissipation
across RIN even at the high end of the universal AC input
voltage (265V AC).
Feed-forward maximum duty-cycle clamping detects changes in line conditions and adjusts the maximum duty cycle
accordingly to eliminate the clamp voltage’s (i.e., the main
power FET’s drain voltage) dependence on the input voltage.
For EMI-sensitive applications, the programmable frequency dithering feature allows up to Q10% variation in
the switching frequency. This spread-spectrum modulation technique spreads the energy of switching harmonics over a wider band while reducing their peaks, helping to meet stringent EMI goals.
The devices include a cycle-by-cycle current limit
that turns off the main and AUX drivers whenever the
internally set threshold of 400mV is exceeded. Eight
consecutive occurrences of current-limit events trigger
hiccup mode, which protects external components by
halting switching for a period of time (tRSTRT) and allowing the overload current to dissipate in the load and
body diode of the synchronous rectifier before soft-start
is reattempted.
The reverse current-limit feature of the devices turns
the AUX driver off for the remaining off period when
VCS exceeds the -100mV threshold. This protects the
transformer core from saturation due to excess reverse
current under some extreme transient conditions.
Current-Mode Control Loop
The advantages of current-mode control over voltagemode control are twofold. First, there is the feed-forward
characteristic brought on by the controller’s ability to adjust
for variations in the input voltage on a cycle-by-cycle basis.
Second, the stability requirements of the current-mode
controller are reduced to that of a single-pole system,
unlike the double pole in voltage-mode control.
The devices use a current-mode control loop where the
scaled output of the error amplifier (COMP) is compared
to a slope-compensated current-sense signal at CSSC.
Input Clamp
When the device is enabled, an internal 18V input clamp
is active. During an overvoltage condition, the clamp
prevents the voltage at the supply input IN from rising
above 18.5V (typ).
When the device is disabled, the input clamp circuitry is
also disabled.
Enable Input
The enable input is used to enable or disable the device.
Driving EN low disables the device. Note that the internal 18V input clamp is also disabled when EN is low.
Therefore, an external 18V zener diode is needed for
certain operating conditions as described below.
15
MAX5974A/MAX5974B/MAX5974C/MAX5974D
Detailed Description
MAX5974A/MAX5974B/MAX5974C/MAX5974D
Active-Clamped, Spread-Spectrum,
Current-Mode PWM Controllers
UVLO on Power Source
The enable input has an accurate threshold of 1.26V
(max). For applications that require a UVLO on the
power source, connect a resistive divider from the power
source to EN to GND as shown in Figure 1. A zener
diode between IN and PGND is required to prevent the
NDRV and AUXDRV gate-drive voltages from exceeding
20V, the maximum allowed gate voltage of power FETs.
The external zener diode should clamp in the following
range:
20V > VZ > VUVLO(MAX)
where VZ is the zener voltage and VUVLO(MAX) is the
maximum wakeup level (16.5V or 8.85V depending on
the device version). An 18V zener diode is the best
choice.
Design the resistive divider by first selecting the value of
REN1 to be on the order of 100kω. Then calculate REN2
as follows:
VEN2 = R EN1 ×
UVLO threshold for the power source, below which the
device is disabled.
The digital output connected to EN should be capable
of withstanding more than the maximum supply voltage.
MCU Control of Enable Input
When using a microcontroller GPIO to control the enable
input, an 18V zener diode is required on IN as shown in
Figure 2.
High-Voltage Logic Control of Enable Input
In the case where EN is externally controlled by a highvoltage open-drain/collector output (e.g., PGOOD indicator of a powered device controller), connect IN to EN
through a resistor REN and connect EN to an open-drain
or open-collector output as shown in Figure 3. Select
REN such that the voltage at IN, when EN is low, is less
than 20V (i.e., the maximum gate voltage of the main and
AUX FETs):
VS(MAX) ×
VEN(MAX)
VS(UVLO)
_
VEN(MAX)
where VEN(MAX) is the maximum enable threshold voltage and is equal to 1.26V and VS(UVLO) is the desired
R EN
< 20V
R EN + RIN
where VS(MAX) is the maximum supply voltage. Obeying
this relationship eliminates the need for an external zener
diode.
The digital output connected to EN should be capable of
withstanding more than 20V.
VS
VS
RIN
RIN
IN
18V
IN
CIN
18V
MAX5974
REN1
CIN
MAX5974_
MCU
DIGITAL
CONTROL
EN
N
EN
REN2
Figure 1. Programmable UVLO for the Power Source
16
I/O
Figure 2. MCU Control of the Enable Input
Active-Clamped, Spread-Spectrum,
Current-Mode PWM Controllers
RIN
Startup Operation
The device starts up when the voltage at IN exceeds 16V
(MAX5974A/MAX5974C) or 8.4V (MAX5974B/MAX5974D)
and the enable input voltage is greater than 1.26V.
IN
CIN
REN
MAX5974
DIGITAL
CONTROL
EN
N
Figure 3. High-Voltage Logic Control of the Enable Input
VS
RIN
IN
MAX5974_
CIN
EN
Figure 4. Always-On Operation
Always-On Operation
For always-on operation, connect EN to IN as shown
in Figure 4. No external zener diode is needed for this
configuration.
Bootstrap Undervoltage Lockout
The devices have an internal bootstrap UVLO that is very
useful when designing high-voltage power supplies (see
the Block Diagrams). This allows the device to bootstrap
itself during initial power-up. The MAX5974A/MAX5974C
soft-start when VIN exceeds the bootstrap UVLO threshold of VINUVR (16V typ).
During normal operation, the voltage at IN is normally derived from a tertiary winding of the transformer
(MAX5974C/MAX5974D). However, at startup there is
no energy being delivered through the transformer;
hence, a special bootstrap sequence is required. In the
Typical Application Circuits, CIN charges through the
startup resistor, RIN, to an intermediate voltage. Only
100FA of the current supplied through RIN is used by
the ICs, the remaining input current charges CIN until
VIN reaches the bootstrap UVLO wake-up level. Once
VIN exceeds this level, NDRV begins switching the
n-channel MOSFET and transfers energy to the secondary and tertiary outputs. If the voltage on the tertiary
output builds to higher than 7V (the bootstrap UVLO
shutdown level), then startup has been accomplished
and sustained operation commences. If VIN drops below
7V before startup is complete, the device goes back to
low-current UVLO. In this case, increase the value of CIN
in order to store enough energy to allow for the voltage
at the tertiary winding to build up.
While the MAX5974A/MAX5974B derive their input voltage from the coupled inductor output during normal
operation, the startup behavior is similar to that of the
MAX5974C/MAX5974D.
Soft-Start
A capacitor from SS to GND, CSS, programs the softstart time. VSS controls the oscillator duty cycle during
startup to provide a slow and smooth increase of the
duty cycle to its steady-state value. Calculate the value
of CSS as follows:
I
×t
C SS = SS-CH SS
2V
where ISS-CH (10FA typ) is the current charging CSS during soft-start and tSS is the programmed soft-start time.
A resistor can also be added from the SS pin to GND to
clamp VSS < 2V and, hence, program the maximum duty
cycle to be less than 80% (see the Duty-Cycle Clamping
section).
17
MAX5974A/MAX5974B/MAX5974C/MAX5974D
Because the MAX5974B/MAX5974D are designed for
use with low-voltage power sources such as wall adapters outputting 12V to 24V, they have a lower UVLO
wake-up threshold of 8.4V.
VS
MAX5974A/MAX5974B/MAX5974C/MAX5974D
Active-Clamped, Spread-Spectrum,
Current-Mode PWM Controllers
n-Channel MOSFET Gate Driver
The NDRV output drives an external n-channel MOSFET.
NDRV can source/sink in excess of 650mA/1000mA
peak current; therefore, select a MOSFET that yields
acceptable conduction and switching losses. The external MOSFET used must be able to withstand the maximum clamp voltage.
Dead Time
Dead time between the main and AUX output edges allow
ZVS to occur, minimizing conduction losses and improving efficiency. The dead time (tDT) is applied to both
leading and trailing edges of the main and AUX outputs
as shown in Figure 5. Connect a resistor between DT and
GND to set tDT to any value between 40ns and 400ns:
p-Channel MOSFET Gate Driver
The AUXDRV output drives an external p-channel
MOSFET with the aid of a level shifter. The level shifter
consists of CAUX, RAUX, and D5 as shown in the Typical
Application Circuits. When AUXDRV is high, CAUX is
recharged through D5. When AUXDRV is low, the gate
of the p-channel MOSFET is pulled below the source by
the voltage stored on CAUX, turning on the pFET.
Add a zener diode between gate to source of the external n-channel and p-channel MOSFETs after the gate
resistors to protect VGS from rising above its absolute
maximum rating during transient condition (see the
Typical Application Circuits).
R DT =
10kΩ
× t DT
40ns
Oscillator/Switching Frequency
The ICs’ switching frequency is programmable between
100kHz and 600kHz with a resistor RRT connected
between RT and GND. Use the following formula to
determine the appropriate value of RRT needed to generate the desired output-switching frequency (fSW):
R RT =
8.7 × 10 9
fSW
where fSW is the desired switching frequency.
BLANKING, tBLK
NDRV
AUXDRV
DEAD TIME, tDT
Figure 5. Dead Time Between AUXDRV and NDRV
18
Active-Clamped, Spread-Spectrum,
Current-Mode PWM Controllers
R CS =
400mV
IPRI
where IPRI is the peak current in the primary side of
the transformer, which also flows through the MOSFET.
When the voltage produced by this current (through the
current-sense resistor) exceeds the current-limit comparator threshold, the MOSFET driver (NDRV) terminates
the current on-cycle, within 35ns (typ).
The devices implement 115ns of leading-edge blanking
to ignore leading-edge current spikes. These spikes
are caused by reflected secondary currents, currentdischarging capacitance at the FET’s drain, and gatecharging current. Use a small RC network for additional
filtering of the leading-edge spike on the sense waveform when needed. Set the corner frequency between
10MHz and 20MHz.
After the leading-edge blanking time, the device monitors VCS for any breaches of the peak current limit of
VCSBL
(BLANKED CS
VOLTAGE)
400mV. The duty cycle is terminated immediately when
VCS exceeds 400mV.
Reverse Current Limit
The devices protect the transformer against saturation
due to reverse current by monitoring the voltage across
RCS while the AUX output is low and the p-channel FET
is on.
Output Short-Circuit Protection
with Hiccup Mode
When the device detects eight consecutive peak currentlimit events, both NDRV and AUXDRV driver outputs are
turned off for a restart period, tRSTRT. After tRSTRT, the
device undergoes soft-start. The duration of the restart
period depends on the value of the capacitor at SS (CSS).
During this period, CSS is discharged with a pulldown current of ISS-DH (2FA typ). Once its voltage reaches 0.15V,
the restart period ends and the device initiates a soft-start
sequence. An internal counter ensures that the minimum
restart period (tRSTRT-MIN) is 1024 clock cycles when the
time required for CSS to discharge to 0.15V is less than
1024 clock cycles. Figure 6 shows the behavior of the
device prior and during hiccup mode.
Frequency Foldback for High-Efficiency
Light-Load Operation
The frequency foldback threshold can be programmed
from 0 to 20% of the full load current using a resistor from
FFB to GND.
VCS-PEAK
(400mV)
HICCUP
DISCHARGE WITH ISS-DH
VSS-HI
SOFT-START
VOLTAGE,
VSS
VSS-DTH
tSS
tRSTRT
Figure 6. Hiccup Mode Timing Diagram
19
MAX5974A/MAX5974B/MAX5974C/MAX5974D
Peak Current Limit
The current-sense resistor (RCS in the Typical
Application Circuits), connected between the source
of the n-channel MOSFET and PGND, sets the current
limit. The current-limit comparator has a voltage trip level
(VCS-PEAK) of 400mV. Use the following equation to calculate the value of RCS:
MAX5974A/MAX5974B/MAX5974C/MAX5974D
Active-Clamped, Spread-Spectrum,
Current-Mode PWM Controllers
When VCSAVG falls below VFFB, the device folds back
the switching frequency to 1/2 the original value to
reduce switching losses and increase the converter efficiency. Calculate the value of RFFB as follows:
R FFB =
10 × ILOAD(LIGHT) × R CS
IFFB
where RFFB is the resistor between FFB and GND,
ILOAD(LIGHT) is the current at light-load conditions that
triggers frequency foldback, RCS is the value of the
sense resistor connected between CS and PGND, and
IFFB is the current sourced from FFB to RFFB (30FA typ).
Duty-Cycle Clamping
The maximum duty cycle is determined by the lowest
of three voltages: 2V, the voltage at SS (VSS), and the
voltage (2.43V - VDCLMP). The maximum duty cycle is
calculated as:
V
D MAX = MIN
2.43V
where VMIN = minimum (2V, VSS, 2.43V - VDCLMP).
SS
By connecting a resistor between SS and ground, the
voltage at SS can be made to be lower than 2V. VSS is
calculated as follows:
VSS = R SS × I SS-CH
where RSS is the resistor connected between SS and
GND, and ISS-CH is the current sourced from SS to RSS
(10FA typ).
DCLMP
To set DMAX using supply voltage feed-forward, connect
a resistive divider between the supply voltage, DCLMP,
and GND as shown in the Typical Application Circuits.
This feed-forward duty-cycle clamp ensures that the
external n-channel MOSFET is not stressed during supply transients. VDCLMP is calculated as follows:
VDCLMP =
R DCLMP2
× VS
R DCLMP1 + R DCLMP2
where RDCLMP1 and RDCLMP2 are the resistive divider
values shown in the Typical Application Circuits and VS
is the input supply voltage.
20
Oscillator Synchronization
The internal oscillator can be synchronized to an external
clock by applying the clock to DITHER/SYNC directly. The
external clock frequency can be set anywhere between
1.1x to 2x the internal clock frequency.
Using an external clock increases the maximum duty
cycle by a factor equal to fSYNC/fSW. This factor should
be accounted for in setting the maximum duty cycle
using any of the methods described in the Duty-Cycle
Clamping section. The formula below shows how the
maximum duty cycle is affected by the external clock
frequency:
D MAX =
VMIN fSYNC
×
2.43V
fSW
where VMIN is described in the Duty-Cycle Clamping
section, fSW is the switching frequency as set by the
resistor connected between RT and GND, and fSYNC is
the external clock frequency.
Frequency Dithering for SpreadSpectrum Applications (Low EMI)
The switching frequency of the converter can be dithered in a range of Q10% by connecting a capacitor from DITHER/SYNC to GND, and a resistor from
DITHER/SYNC to RT as shown in the Typical Application
Circuits. This results in lower EMI.
A current source at DITHER/SYNC charges the capacitor CDITHER to 2V at 50FA. Upon reaching this trip point,
it discharges CDITHER to 0.4V at 50FA. The charging
and discharging of the capacitor generates a triangular
waveform on DITHER/SYNC with peak levels at 0.4V and
2V and a frequency that is equal to:
fTRI =
50µA
C DITHER × 3.2V
Typically, fTRI should be set close to 1kHz. The resistor
RDITHER connected from DITHER/SYNC to RT determines the amount of dither as follows:
%DITHER =
R RT
4
×
3 RDITHER
where %DITHER is the amount of dither expressed as a
percentage of the switching frequency. Setting RDITHER
to 10 x RRT generates Q10% dither.
Active-Clamped, Spread-Spectrum,
Current-Mode PWM Controllers
m=
R CSSC × 50µA × fSW
80%
where m is the ramp rate of the slope-compensation
signal, RCSSC is the value of the resistor connected
between CSSC and CS used to program the ramp rate,
and fSW is the switching frequency.
Error Amplifier
The MAX5974A/MAX5974B include an internal error
amplifier with a sample-and-hold input. The feedback
input of the MAX5974C/MAX5974D is continuously connected. The noninverting input of the error amplifier is
connected to the internal reference and feedback is
provided at the inverting input. High open-loop gain and
unity-gain bandwidth allow good closed-loop bandwidth
and transient response. Calculate the power-supply output voltage using the following equation:
R
+ R FB2
VOUT = VREF × FB1
R FB2
where VREF = 1.52V for the MAX5974A/MAX5974B
and VREF = 1.215V for the MAX5974C/MAX5974D. The
amplifier’s noninverting input is internally connected to
a soft-start circuit that gradually increases the reference
voltage during startup. This forces the output voltage to
come up in an orderly and well-defined manner under
all load conditions.
Applications Information
Startup Time Considerations
The bypass capacitor at IN, CIN, supplies current
immediately after the devices wake up (see the Typical
Application Circuits). Large values of CIN increase
the startup time, but also supply gate charge for more
cycles during initial startup. If the value of CIN is too
small, VIN drops below 7V because NDRV does not have
enough time to switch and build up sufficient voltage
across the tertiary output (MAX5974C/MAX5974D) or
coupled inductor output (MAX5974A/MAX5974B), which
powers the device. The device goes back into UVLO
and does not start. Use a low-leakage capacitor for CIN.
Typically, offline power supplies keep startup times to
less than 500ms even in low-line conditions (85V AC
input for universal offline or 36V DC for telecom applications). Size the startup resistor, RIN, to supply both the
maximum startup bias of the device (150FA) and the
charging current for CIN. CIN must be charged to 16V
within the desired 500ms time period. CIN must store
enough charge to deliver current to the device for at
least the soft-start time (tSS) set by CSS. To calculate the
approximate amount of capacitance required, use the
following formula:
IG = Q GTOT fSW
(I + I )(t )
CIN = IN G SS
VHYST
where IIN is the ICs’ internal supply current (1.8mA)
after startup, QGTOT is the total gate charge for the
n-channel and p-channel FETs, fSW is the ICs’ switching frequency, VHYST is the bootstrap UVLO hysteresis
(9V typ), and tSS is the soft-start time. RIN is then calculated as follows:
RIN ≅
VS(MIN) − VINUVR
I START
where VS(MIN) is the minimum input supply voltage for
the application (36V for telecom), VINUVR is the bootstrap UVLO wake-up level (16V), and ISTART is the IN
supply current at startup (150FA max).
21
MAX5974A/MAX5974B/MAX5974C/MAX5974D
Programmable Slope Compensation
The device generates a current ramp at CSSC such that
its peak is 50FA at 80% duty cycle of the oscillator. An
external resistor connected from CSSC to the CS then
converts this current ramp into programmable slopecompensation amplitude, which is added to the currentsense signal for stability of the peak current-mode
control loop. The ramp rate of the slope compensation
signal is given by:
MAX5974A/MAX5974B/MAX5974C/MAX5974D
Active-Clamped, Spread-Spectrum,
Current-Mode PWM Controllers
Choose a higher value for RIN than the one calculated
above if a longer startup time can be tolerated in order
to minimize power loss on this resistor.
Active Clamp Circuit
Traditional clamp circuits prevent transformer saturation
by channeling the magnetizing current (IM) of the transformer onto a dissipative RC network. To improve efficiency, the active clamp circuit recycles IM between the
magnetizing inductance and clamp capacitor. VCLAMP
is given by:
VCLAMP =
2π L MAG × C CLAMP
where VS is the voltage of the power source and D is
the duty cycle. To select n-channel and p-channel FETs
with adequate breakdown voltages, use the maximum
value of VCLAMP. VCLAMP(MAX) occurs when the input
voltage is at its minimum and the duty cycle is at its
maximum. VCLAMP(MAX-NORMAL) during normal operation is therefore:
VS(MIN)
NP × VO
1−
N S × VS(MIN)
where VS(MIN) is the minimum voltage of the power
source, NP/NS is the primary to secondary turns ratio,
and VO is the output voltage. The clamp capacitor,
n-channel, and p-channel FETs must have breakdown
voltages exceeding this level.
If feed-forward maximum duty-cycle clamp is used then:
V
 V

D MAX-FF = MIN = 1 − DCLMP 
2.43 
2.43 


V
RDCLMP2
= 1 − S ×

 2.43 R DCLMP1 + R DCLMP2 
Therefore, VCLAMP(MAX-FF) during feed-forward maximum duty clamp is:
VCLAMP(MAX-FF) =
=
22
VS
1 − D MAX −FF
2.43 × (R DCLMP1 + R DCLMP2 )
RDCLMP2
Additionally, CCLAMP should be chosen such that the
complex poles formed with magnetizing inductance
(LMAG) and CCLAMP are 2x to 4x away from the loop
bandwidth:
1-D
VS
1− D
VCLAMP(MAX-NORMAL) =
The AUX driver controls the p-channel FET through a
level shifter. The level shifter consists of an RC network
(formed by CAUX and RAUX) and diode D5, as shown in
the Typical Application Circuits. Choose RAUX and CAUX
so that the time constant exceeds 100/fSW. Diode D5 is a
small-signal diode with a voltage rating exceeding 25V.
> 3 × fBW
Bias Circuit
Optocoupler Feedback (MAX5974C/MAX5974D)
An in-phase tertiary winding is needed to power the bias
circuit when using optocoupler feedback. The voltage
across the tertiary VT during the on-time is:
N
VT = VOUT × T
N
S
where VOUT is the output voltage and NT/NS is the turns
ratio from the tertiary to the secondary winding. Select the
turns ratio so that VT is above the UVLO shutdown level
(7.35V max) by a margin determined by the holdup time
needed to “ride through” a brownout.
Coupled-Inductor Feedback (MAX5974A/MAX5974B)
When using coupled-inductor feedback, the power for
the devices can be taken from the coupled inductor during the off-time. The voltage across the coupled inductor, VCOUPLED, during the off-time is:
N
VCOUPLED = VOUT × C
N
O
where VOUT is the output voltage and NC/NO is the
turns ratio from the coupled output to the main output
winding. Select the turns ratio so that VCOUPLED is
above the UVLO shutdown level (7.5V max) by a margin
determined by the holdup time needed to “ride through”
a brownout.
This voltage appears at the input of the devices, less
a diode drop. An RC network consisting of RSNUB and
CSNUB is for damping the reverse recovery transients of
diode D6.
Active-Clamped, Spread-Spectrum,
Current-Mode PWM Controllers
N
VCOUPLED-ON = −(VS × S
NP
NC
NO
− VOUT )
where VS is the input supply voltage.
Care must be taken to ensure that the voltage at FB
(equal to VCOUPLED-ON attenuated by the feedback
resistive divider) is not more than 5V:
VFB-ON = VCOUPLED-ON ×
R FB2
< 5V
R
( FB1 + R FB2 )
If this condition is not met, a signal diode should be
placed from GND (anode) to FB (cathode).
Typically, there are two sources of noise emission in a
switching power supply: high di/dt loops and high dV/dt
surfaces. For example, traces that carry the drain current
often form high di/dt loops. Similarly, the heatsink of the
main MOSFET presents a dV/dt source; therefore, minimize the surface area of the MOSFET heatsink as much
as possible. Keep all PCB traces carrying switching currents as short as possible to minimize current loops. Use
a ground plane for best results.
For universal AC input design, follow all applicable
safety regulations. Offline power supplies can require
UL, VDE, and other similar agency approvals.
Refer to the MAX5974A and MAX5974C Evaluation Kit
data sheets for recommended layout and component
values.
23
MAX5974A/MAX5974B/MAX5974C/MAX5974D
Layout Recommendations
During on-time, the coupled output is:
MAX5974A/MAX5974B/MAX5974C/MAX5974D
Active-Clamped, Spread-Spectrum,
Current-Mode PWM Controllers
Typical Application Circuits
VS
36V TO 57V
L1
3.3mH
CBULK
33µF
D1
NT
RIN
100kI
D2
L2
6.8µH
CIN
1µF
25V
D3
RDCLMP1
30.1kI
1%
PGOOD
NP
IN
T1
NS
RGATE2
10I
RGATE1
10I
N
RFB2
2.49kI
1%
N
DCLMP
SS
RDT
16.9kI 1%
DT
CDITHER
10nF
RRT
14.7kI 1%
N1
5i412DP
MAX5974C
MAX5974D
IN
N3
FDS3692
(OPTOCOUPLER
FEEDBACK)
DITHER/
SYNC
CCLAMP
47nF
RGATE3
10I
NDRV
N
P
CAUX
47nF
RFFB
10.0kI 1%
RF
499I 1%
FFB
RG1
RG2
121kI 1% 200kI 1%
ROPTO3
4.99kI
1%
ROPTO1
825I
1%
CCOMP1
2.2nF
U1
FOD817CSD
RGATE4
10I
AUXDRV
RT
N4
IRF6217
RBIAS
4.02kI
1%
CINT
0.1µF
CF
330pF
FB
COMP
D5
CSSC
PGND
RCOMP2
499I
1%
CCOMP2
6.8pF
CS
GND
24
N2
5i412DP
D4
EN
CSS
0.1µF
ROPTO2
1kI
1%
COUT5
COUT1 COUT2 COUT3 COUT4 0.1µF
REN
100kI
RDCLMP2
750I 1%
5V, 5A
RFB1
7.5kI
1%
RCSSC
4.02kI 1%
RAUX
10kI
RCOMP2
2.00kI
1%
U2
TLV4314AIDBVT-1.24V
RCS
0.2I
Active-Clamped, Spread-Spectrum,
Current-Mode PWM Controllers
D6
RFB1
54.9kI 1%
CSNUB RSNUB
10pF 69.8I 1%
VS
36V TO 57V
CBULK
33µF
63V
TO FB
RFB2
10kI 1%
RIN
100kI
CIN
1µF
25V
RDCLMP1
30.1kI
1%
NP
T1
RGATE2
10I
D3
NS
RGATE1
10I
COUT1 COUT2 COUT3 COUT4
COUT5
0.1µF
N
DCLMP
N1
5i412DP
CSS
0.1µF
SS
MAX5974A
MAX5974B
RDT
16.9kI 1%
DT
5V, 5A
D4
EN
CDITHER
10nF
N2
5i412DP
N
IN
RDCLMP2
750I 1%
4 x 47µF
6.3V
NO
REN
100kI
PGOOD
LCOUPLED
NC
(COUPLED INDUCTOR
FEEDBACK)
DITHER/
SYNC
RRT
14.7kI 1%
RGATE3
10I
NDRV
N3
FDS3692
CCLAMP
47nF
N
RGATE4
10I
P
AUXDRV
RT
CAUX
47nF
RFFB
10kI 1%
N4
IRF6217
RF
499I 1%
FFB
CS
CF
330pF
FB
CCOMP
4.7nF
RZ
2kI 1%
D5
COMP
GND
CINT
47nF
CSSC
PGND
RAUX
10kI
RCSSC
4.02kI 1%
RCS
0.2I
25
MAX5974A/MAX5974B/MAX5974C/MAX5974D
Typical Application Circuits (continued)
MAX5974A/MAX5974B/MAX5974C/MAX5974D
Active-Clamped, Spread-Spectrum,
Current-Mode PWM Controllers
Typical Application Circuits (continued)
D1
L1
VS
NT
CBULK
D2
RIN
L2
CIN
T1
D3
NP
NS
RGATE2
COUT1 COUT2 COUT3 COUT4
RGATE1
N
IN
RDCLMP1
REN
100kI
N2
RFB1
RFB2
D4
PGOOD
EN
N
DCLMP
N1
RDCLMP2
CSS
SS
RDT
MAX5974C
MAX5974D
DT
RDITHER
CDITHER
CCLAMP
RGATE3
DITHER/
SYNC
RRT
NDRV
N
N3
RGATE4
P
AUXDRV
RT
N4
CAUX
RFFB
FFB
CS
CSSC
FB
RCSSC
COMP
Rz
GND
D5
RAUX
PGND
RCS
CCOMP
CHF
Chip Information
PROCESS: BiCMOS
26
Package Information
For the latest package outline information and land patterns
(footprints), 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
Active-Clamped, Spread-Spectrum,
Current-Mode PWM Controllers
REVISION
NUMBER
REVISION
DATE
0
6/10
Initial release
1
9/10
Introduced the MAX5974B/MAX5974D. Updated the Absolute Maximum
Ratings, Electrical Characteristics, Pin Description, the p-Channel MOSFET
Gate Driver, Frequency Foldback for High-Efficiency Light-Load Operation
sections, and Typical Application Circuits.
2
6/11
Added internal zener diode information
DESCRIPTION
PAGES
CHANGED
—
1, 2, 3, 12, 15, 17,
19, 21, 23, 24, 25
1–10, 12–17, 19–25
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.
Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600
© 2011
Maxim Integrated Products 27
Maxim is a registered trademark of Maxim Integrated Products, Inc.
MAX5974A/MAX5974B/MAX5974C/MAX5974D
Revision History