MAXIM MAX5058EUI

19-3045; Rev 0; 10/03
Parallelable Secondary-Side Synchronous Rectifier
Driver and Feedback-Generator Controller ICs
Features
♦ Clean Drive Waveforms for Synchronous
MOSFETs
An on-board error amplifier with a versatile current reference output enables virtually unlimited possibilities in
reference-voltage generation. Reference voltage for the
error amplifier is generated by connecting an appropriate resistor to this output.
♦ Internal Remote Voltage-Sense Amplifier
Low on-resistance margining MOSFETs integrated onchip allow for implementation of a margining circuit
without the use of external switches. The MAX5058 provides a 5V LDO output for logic-level MOSFETs while
the MAX5059 provides a 10V LDO output for conventional 10V MOSFETs.
The MAX5058/MAX5059 are designed to enable paralleling of multiple power supplies for accurate current
sharing using a simple 2-wire, differential, current-share
bus. Parallelability enables expansion of the power
capabilities and simplifies thermal management in highoutput-current applications. When used in conjunction
with the MAX5051, the primaries can also be synchronized and operated 180 degrees out of phase.
The MAX5058/MAX5059 are available in a 28-pin thermally enhanced TSSOP package and operate over a
wide -40°C to +125°C temperature range.
Warning: The MAX5058/MAX5059 are designed to
work in circuits that contain high voltages. Exercise
caution.
Applications
Isolated Telecom Power Supplies
Isolated Networking Power Supplies
±48V Power-Supply Modules
Industrial Power Supplies
±48V/±12V Server Power Supplies
♦ Utilization of a Look-Ahead Signal from the
Primary for Proper Turn-On/Turn-Off Times
♦ Synchronous Rectifier Drivers Capable of
Sourcing and Sinking Up to 2A Peak Current
♦ Internal Gate-Voltage Regulator for 5V (MAX5058)
or 10V (MAX5059) Gate-Drive Voltage
♦ Internal Error Amplifier
♦ Accurate Differential Current-Share/Force Circuit
Allows Paralleling of Several Power Supplies for
High Output Current
♦ Flexible Reference-Voltage Generation
♦ Output Voltage Regulation Down to 0.5V
♦ Low Quiescent Current Consumption of 2.5mA
♦ Integrated Digital Output Margining Circuit Saves
External Parts and Board Space
♦ 30ns Propagation Delay Time from Pulse Input
to Output
♦ Automatic Detection of Discontinuous Current
Conduction and Turn-Off of the Freewheeling
MOSFET
♦ High Efficiency at Low Output Currents and
Reverse-Current Protection
♦ Open-Drain Overtemperature Warning Flag
♦ 28-Pin Thermally Enhanced TSSOP Package
Ordering Information
PART
TEMP RANGE
PINPACKAGE
VREG
(V)
-40°C to +125°C
28 TSSOP-EP*
MAX5058EUI
-40°C to +85°C
28 TSSOP-EP*
5
MAX5059AUI
-40°C to +125°C
28 TSSOP-EP*
10
MAX5059EUI
-40°C to +85°C
28 TSSOP-EP*
10
MAX5058AUI
5
*EP = Exposed paddle.
Pin Configuration appears at end of data sheet.
________________________________________________________________ Maxim Integrated Products
For pricing, delivery, and ordering information, please contact Maxim/Dallas Direct! at
1-888-629-4642, or visit Maxim’s website at www.maxim-ic.com.
1
MAX5058/MAX5059
General Description
The MAX5058/MAX5059 enable secondary-side synchronous rectification in isolated power supplies using
widely available power MOSFETs. These devices facilitate the commutation of the secondary-side MOSFETs by
providing a clean gate-drive signal that is synchronized
to the power MOSFET switching in the primary side of
the isolation transformer. The MAX5058/MAX5059 complement the MAX5051 and MAX5042/MAX5043 primaryside PWM ICs and enable the design of high-efficiency
synchronously rectified isolated power supplies.
Simultaneous conduction of the primary side and the
freewheeling synchronous rectifier MOSFET is avoided
by having a look-ahead signal (before the primary-side
MOSFETs turn ON), thus eliminating large current spikes
resulting from a shorted transformer secondary.
MAX5058/MAX5059
Parallelable Secondary-Side Synchronous Rectifier
Driver and Feedback-Generator Controller ICs
ABSOLUTE MAXIMUM RATINGS
V+ to GND .............................................................-0.3V to +30V
PGND to GND .......................................................-0.3V to +0.3V
COMPV, VREG, VDR, TSF to GND......................... -0.3V to +14V
All Other Pins to GND ..................................-0.3V to (VP + 0.3V)
VREG Source Current .........................................................50mA
COMPV, RMGU, RMGD, TSF Sink Current ....................... 30mA
VP to GND ................................................................-0.3V to +6V
VSO, CSO Source/Sink Current ......................................... ±5mA
SFP Source Current ............................................................. 5mA
QREC, QSYNC Continuous Current....................................50mA
QREC, QSYNC Current < 500ns..............................................5A
Continuous Power Dissipation (TA = +70°C)
28-Pin TSSOP (derate 23.8mW/°C above +70°C). ....1905mW
Junction Temperature ......................................................+150°C
Operating Temperature Ranges
MAX5058EUI, MAX5059EUI ............................-40°C to +85°C
MAX5058AUI, MAX5059AUI..........................-40°C to +125°C
Storage Temperature Range .............................-65°C to +150°C
Lead Temperature (soldering, 10s) .................................+300°C
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
(V+ = +12V, GND = PGND = 0, VDR = VREG, CQSYNC = CQREC = 0, ZCP = ZCN = BUFIN = CSP = CSN = SFN = VSN = GND, VIREF =
VVSP = 1.785V, CVREG = 2.2µF, CVP = 1µF, CCOMPS = 0.1µF, CSFP = 68nF, TA = TMIN to TMAX, unless otherwise noted. Typical values
are at TA = +25°C.)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
POWER SUPPLY
Supply Voltage Range
V+
Quiescent Supply Current
IQ
Switching Supply Current
ISW
MAX5058
4.5
28.0
MAX5059
9.3
28.0
2.5
fSW = 250kHz at BUFIN
MAX5058
4.5
MAX5059
6
5
V
mA
mA
IREF: REFERENCE CURRENT OUTPUT
Reference Current
Reference Current Variation
IIREF
∆IIREF
Reference Voltage Compliance
Range
VIREF = 1.785V
49.2
51.1
µA
VIREF = 0.5V to 2.5V
-0.1
50
+0.1
%/V
Guaranteed by reference current variation
test
0.5
2.5
V
VREG: LOW-DROPOUT REGULATOR
Regulator Output
VVREG
Line Regulation
Dropout
IVREG = 0 to 30mA
MAX5058
4.75
5
5.25
MAX5059
9.4
10
10.6
MAX5058, V+ = 6V to 28V
25
MAX5059, V+ = 11V to 28V
25
MAX5058
V+ = 4.5V,
IVREG = 30mA
200
350
MAX5059
V+ = 9.3V,
IVREG = 30mA
200
350
VDROP
V
mV
mV
VP: INTERNAL REGULATOR
Regulator Output Setpoint
VVP
IVP = 0 to 5mA
3.8
4.3
V
+6.5
mV
+2.5
µA
ZC: ZERO-CURRENT COMPARATOR
Zero-Current Comparator
Threshold
Zero-Current Comparator Input
Current
2
VZCTH
IZC
TA = +25°C
+3.5
+5
-2.5
_______________________________________________________________________________________
Parallelable Secondary-Side Synchronous Rectifier
Driver and Feedback-Generator Controller ICs
(V+ = +12V, GND = PGND = 0, VDR = VREG, CQSYNC = CQREC = 0, ZCP = ZCN = BUFIN = CSP = CSN = SFN = VSN = GND, VIREF =
VVSP = 1.785V, CVREG = 2.2µF, CVP = 1µF, CCOMPS = 0.1µF, CSFP = 68nF, TA = TMIN to TMAX, unless otherwise noted. Typical values
are at TA = +25°C.)
PARAMETER
SYMBOL
Zero-Current Comparator Input
Range
VZC
Zero-Current Comparator
Propagation Delay
tZC
CONDITIONS
MIN
TYP
-0.1
MAX
UNITS
+1.5
V
10mV overdrive, from when VZCP - VZCN is
greater than VZCTH to when QSYNC goes
low
65
ns
BUFIN rising to QREC rising or QSYNC
falling
40
ns
BUFIN: SYNCHRONIZING PULSE INPUT
BUFIN to Output Propagation
Delay
BUFIN Input Current
tpd
IBUFIN
BUFIN Input Capacitance
CBUFIN
BUFIN Input-Logic High
VHBUFIN
BUFIN Input-Logic Low
VLBUFIN
-1
+1
10
µA
pF
2.4
V
0.8
V
MARGINING INPUTS
RMGD Resistance
RRMGD
Sinking 10mA
6.5
11
Ω
RMGU Resistance
RRMGU
Sinking 10mA
6.5
11
Ω
MRGD Input-Logic High
VHMRGD
MRGD Input-Logic Low
VLMRGD
0.8
V
MRGU Input-Logic High
VHMRGU
MRGU Input-Logic Low
VLMRGU
MRGU, MRGD Input Resistance
RMRGD,
RMRGU
40
RMGU, RMGD Leakage Current
IRMGU,
IRMGD
-100
2.4
V
2.4
V
0.8
V
kΩ
+100
nA
DRIVER OUTPUTS
QREC, QSYNC Peak Source
Current
IQREC_SO,
IQSYNC_SO
QREC, QSYNC Output-Voltage
High
VQREC_H,
VQSYNC_H
QREC, QSYNC Low-to-High
Delay Time
tPDLH
QREC, QSYNC Peak Sink Current
IQREC_SI,
IQSYNC_SI
QREC, QSYNC Output-Voltage
Low
VQREC_L,
VQSYNC_L
QREC, QSYNC High-to-Low
Delay Time
tPDHL
2
Measured with respect to
VVDR, sourcing 50mA
A
MAX5058
75
150
MAX5059
75
150
CQREC = CQSYNC = 0
30
CQREC = CQSYNC = 5nF
70
ns
2
Sinking 50mA
A
MAX5058
50
100
MAX5059
50
100
CQREC = CQSYNC = 0
40
CQREC = CQSYNC = 5nF
70
mV
mV
ns
_______________________________________________________________________________________
3
MAX5058/MAX5059
ELECTRICAL CHARACTERISTICS (continued)
MAX5058/MAX5059
Parallelable Secondary-Side Synchronous Rectifier
Driver and Feedback-Generator Controller ICs
ELECTRICAL CHARACTERISTICS (continued)
(V+ = +12V, GND = PGND = 0, VDR = VREG, CQSYNC = CQREC = 0, ZCP = ZCN = BUFIN = CSP = CSN = SFN = VSN = GND, VIREF =
VVSP = 1.785V, CVREG = 2.2µF, CVP = 1µF, CCOMPS = 0.1µF, CSFP = 68nF, TA = TMIN to TMAX, unless otherwise noted. Typical values
are at TA = +25°C.)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
-50
+50
nA
0
2.5
V
-5
+5
mV
200
mV
ERROR AMPLIFIER
Inverting Input Current
IINV
Error-Amplifier Input Range
VINV
Error-Amplifier Input Offset
VOS
ICOMPV = 100µA to 5mA
Error-Amplifier Output-Voltage
Low
VCOMPV
Error-Amplifier Unity-Gain BW
GBW
RCOMP = 220Ω, ICOMP = 5mA
1.3
MHz
Error-Amplifier Voltage Gain
AVOL
RCOMPV = 220Ω, ICOMP = 5mA
80
dB
Error-Amplifier PSRR
PSRR
60
dB
1
MΩ
COMPV Output Resistance to
Ground
ICOMPV = 5mA
(Note 1)
REMOTE-SENSE AMPLIFIER (RSA)
VSN Input Current
IVSN
-100
+100
µA
VSP Input Current
IVSP
-20
+100
µA
Input Common-Mode Range
Input Offset Voltage
-0.3
VOSRSA
Remote-Sense Amplifier Gain
V
-4
8
Ω
IVSO = -0.5mA to +0.5mA
1
MHz
Output Impedance
Amplifier -3dB Frequency
+3.8
IVSO = -0.5mA to +0.5mA
GRS
IVSO = -0.5mA to +0.5mA
CSN Input Current
ICSN
-0.3V ≤ VCSN ≤ +3.8V,
-0.3V ≤ VCSP ≤ +3.8V
CSP Input Current
ICSP
0.9925
1
mV
1.0075
V/V
+150
µA
CURRENT-SENSE AMPLIFIER (CSA)
Input Offset Voltage
Current-Sense Amplifier Gain
GCSA
-150
-0.3V ≤ VCSP ≤ +3.8V
-40
+150
µA
ICSO = -500µA to +500µA (Note 2)
+20
+25
+30
mV
ICSO = -500µA to +500µA
19.8
20
20.2
V/V
100
mV
-0.3
+3.8
V
0.415
0.570
V
0.1
3.0
Input Differential-Mode Range
Input Common-Mode Range
Output-Voltage Level Shift
Output Voltage Range
Amplifier -3dB Frequency
VLS
(Note 2)
VCSO(MIN)
ICSO = -500µA to +500µA
f-3dB
ICSO = -500µA to +500µA
50
V
kHz
SHARE-FORCE AMPLIFIER (SFA)
Sink Current
Source Current
4
60
500
_______________________________________________________________________________________
µA
µA
Parallelable Secondary-Side Synchronous Rectifier
Driver and Feedback-Generator Controller ICs
(V+ = +12V, GND = PGND = 0, VDR = VREG, CQSYNC = CQREC = 0, ZCP = ZCN = BUFIN = CSP = CSN = SFN = VSN = GND, VIREF =
VVSP = 1.785V, CVREG = 2.2µF, CVP = 1µF, CCOMPS = 0.1µF, CSFP = 68nF, TA = TMIN to TMAX, unless otherwise noted. Typical values
are at TA = +25°C.)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
CURRENT-ADJUST AMPLIFIER (CAA)
Transconductance
500
Common-Mode Input Voltage
Range
0.45
Output Voltage Range
2.55
0.85
TA = +25°C
Offset Voltage
20
Open-Loop Gain
µA/V
42
V
2.75
V
65
mV
72
dB
CURRENT-ADJUST VOLTAGE-TO-CURRENT CONVERTER
Input Voltage Range
0.75
Input Voltage Offset
2.75
1.25
Output Voltage Range
0.5
Transconductance
V
2.5
1.15
Maximum Current Adjustment
Value
1.38
1.5
V
V
µA/V
1.66
µA
THERMAL SHUTDOWN
+125
°C
Thermal Warning Flag Hysteresis
15
°C
Internal Thermal-Shutdown Level
+160
°C
15
°C
Thermal Warning Flag Level
When TSF pulls low
Internal Thermal-Shutdown
Hysteresis
TSF Maximum Output Voltage
ITSF = 5mA
TSF Output Leakage Current
120
mV
0.1
µA
Note 1: Output resistance to ground used for unity-gain stability.
Note 2: VCSO = GCSA(VCSP - VCSN) + VLS.
_______________________________________________________________________________________
5
MAX5058/MAX5059
ELECTRICAL CHARACTERISTICS (continued)
Typical Operating Characteristics
(V+ = +12V, GND = PGND = 0, VDR = VREG, CQSYNC = CQREC = 0, ZCP = ZCN = BUFIN = CSP = CSN = SFN = VSN = GND, VIREF =
VVSP = 1.785V, VCOMPS = 0.5V, CVREG = 2.2µF, CVP = 1µF, CCOMPS = 0.1µF, CSFP = 68nF, TA = +25°C, unless otherwise noted.)
5.0020
5.0015
5.0010
5.0005
5.0000
4.9995
4.9990
50.09
50.07
50.05
50.03
50.01
49.99
49.97
49.95
49.93
0
3
6
12 15 18 21 24 27 30
9
-40 -25 -10 5 20 35 50 65 80 95 110 125
0 10 20 30 40 50 60 70 80 90 100 110
TEMPERATURE (°C)
IVREG (mA)
LDO OUTPUT VOLTAGE (VREG)
vs. TEMPERATURE (MAX5058)
LDO OUTPUT VOLTAGE (VVREG)
vs. INPUT VOLTAGE (MAX5059)
V+ (V)
LDO OUTPUT VOLTAGE (VVREG)
vs. LOAD CURRENT (MAX5058)
5.00
VVREG (V)
4.98
4.96
4.94
4.92
4.90
4.88
4.86
5.010
5.008
5.006
5.004
5.002
5.000
4.998
4.996
4.994
4.992
4.990
4.988
4.986
4.984
4.982
4.980
10.010
10.008
10.002
10.000
9.998
TEMPERATURE (°C)
0
3
6
9
12 15 18 21 24 27 30
V+ (V)
IREF OUTPUT CURRENT
vs. IREF OUTPUT VOLTAGE
LDO OUTPUT VOLTAGE (VVREG)
vs. TEMPERATURE (MAX5059)
50.5
50.0
49.0
IIREF (µA)
49.5
10.010
VVREG (V)
MAX5058/59 toc08
MAX5058/59 toc07
51.0
10.015
10.005
48.5
10.000
48.0
9.995
47.5
9.990
47.0
9.985
46.5
46.0
9.980
-40 -25 -10 5 20 35 50 65 80 95 110 125
TEMPERATURE (°C)
6
10.012
10.004
IVREG (mA)
10.020
10.016
10.006
-40 -25 -10 15 20 35 50 65 80 95 110 125
10.025
10.018
10.014
0 10 20 30 40 50 60 70 80 90 100 110
10.030
10.020
VVREG (V)
5.02
MAX5058/59 toc05
MAX5058/59 toc04
5.04
MAX5058/59 toc03
50.13
50.11
10.10
10.08
10.06
10.04
10.02
10.00
9.98
9.96
9.94
9.92
9.90
9.88
9.86
9.84
9.82
9.80
MAX5058/59 toc06
5.0030
5.0025
VIREF = 1.785V
50.15
IREF (µA)
VVREG (V)
5.0040
5.0035
50.17
VVREG (V)
IVREG = 0mA
5.0045
MAX5058/59 toc01
5.0050
LDO OUTPUT VOLTAGE (VVREG)
vs. LOAD CURRENT (MAX5059)
MAX5058/59 toc02
IREF OUTPUT CURRENT
vs. TEMPERATURE
LDO OUTPUT VOLTAGE (VVREG)
vs. INPUT VOLTAGE (MAX5058)
VVREG (V)
MAX5058/MAX5059
Parallelable Secondary-Side Synchronous Rectifier
Driver and Feedback-Generator Controller ICs
0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0
VIREF (V)
_______________________________________________________________________________________
Parallelable Secondary-Side Synchronous Rectifier
Driver and Feedback-Generator Controller ICs
12 15 18 21 24 27 30
3
6
9
MAX5058/59 toc11
MAX5058/59 toc10
0
V+ (V)
12 15 18 21 24 27 30
2.40
2.35
2.30
2.25
2.20
2.15
2.10
2.05
2.00
-40 -25 -10 5 20 35 50 65 80 95 110 125
V+ (V)
TEMPERATURE (°C)
SWITCHING SUPPLY CURRENT
vs. INPUT VOLTAGE (MAX5058)
QUIESCENT SUPPLY CURRENT
vs. TEMPERATURE (MAX5059)
5.0
MAX5058/59 toc12
3.0
2.9
2.8
4.0
2.6
3.0
IV+ (mA)
3.5
2.5
fSW = 250kHz
4.5
2.7
2.5
2.4
2.0
2.3
1.5
2.2
1.0
2.1
0.5
0
2.0
3 5
-40 -25 -10 5 20 35 50 65 80 95 110 125
7 9 11 13 15 17 19 21 23 25 27 29
TEMPERATURE (°C)
V+ (V)
SWITCHING SUPPLY CURRENT
vs. TEMPERATURE (MAX5058)
SWITCHING SUPPLY CURRENT
vs. INPUT VOLTAGE (MAX5059)
fSW = 250kHz
4.6
6.0
5.5
MAX5058/59 toc14
5.0
4.8
2.55
2.50
2.45
MAX5058/59 toc13
9
2.60
4.4
IV+ (mA)
4.2
4.0
3.8
3.6
fSW = 250kHz
5.0
4.5
MAX5058/59 toc15
6
3.0
2.8
2.6
2.4
2.2
2.0
1.8
1.6
1.4
1.2
1.0
0.8
0.6
0.4
0.2
0
IV+ (mA)
IV+ (mA)
3
IV+ (mA)
0
QUIESCENT SUPPLY CURRENT
vs. TEMPERATURE (MAX5058)
QUIESCENT SUPPLY CURRENT
vs. INPUT VOLTAGE (MAX5059)
MAX5058/59 toc09
3.0
2.8
2.6
2.4
2.2
2.0
1.8
1.6
1.4
1.2
1.0
0.8
0.6
0.4
0.2
0
IV+ (mA)
IV+ (mA)
QUIESCENT SUPPLY CURRENT
vs. INPUT VOLTAGE (MAX5058)
4.0
3.5
3.0
2.5
2.0
1.5
1.0
3.4
3.2
3.0
-40 -25 -10 5 20 35 50 65 80 95 110 125
TEMPERATURE (°C)
0.5
0
3 5 7 9 11 13 15 17 19 21 23 25 27 29
V+ (V)
_______________________________________________________________________________________
7
MAX5058/MAX5059
Typical Operating Characteristics (continued)
(V+ = +12V, GND = PGND = 0, VDR = VREG, CQSYNC = CQREC = 0, ZCP = ZCN = BUFIN = CSP = CSN = SFN = VSN = GND, VIREF =
VVSP = 1.785V, VCOMPS = 0.5V, CVREG = 2.2µF, CVP = 1µF, CCOMPS = 0.1µF, CSFP = 68nF, TA = +25°C, unless otherwise noted.)
Typical Operating Characteristics (continued)
(V+ = +12V, GND = PGND = 0, VDR = VREG, CQSYNC = CQREC = 0, ZCP = ZCN = BUFIN = CSP = CSN = SFN = VSN = GND, VIREF =
VVSP = 1.785V, VCOMPS = 0.5V, CVREG = 2.2µF, CVP = 1µF, CCOMPS = 0.1µF, CSFP = 68nF, TA = +25°C, unless otherwise noted.)
SWITCHING SUPPLY CURRENT
vs. TEMPERATURE (MAX5059)
0.014
0.013
VSO OUTPUT (dB)
5.4
5.2
5.0
4.8
VVSP = 1.785V
4.6
5
0
-5
0.012
0.011
0.010
-10
-15
-20
-25
0.009
4.4
10
-30
4.2
0.008
-35
4.0
0.007
-40
-40 -25 -10 5 20 35 50 65 80 95 110 125
-40 -25 -10 5 20 35 50 65 80 95 110 125
TEMPERATURE (°C)
TEMPERATURE (°C)
25.0
24.9
INPUT OFFSET (mV)
CSA GAIN (V/V)
20.02
20.01
20.00
19.99
1k
10k
MAX5058/59 toc20
20.03
0.1k
24.8
24.7
24.6
24.5
24.4
24.3
19.98
24.2
19.97
24.1
24.0
19.96
-40 -25 -10 5 20 35 50 65 80 95 110 125
-40 -25 -10 5 20 35 50 65 80 95 110 125
TEMPERATURE (°C)
TEMPERATURE (°C)
CSA GAIN
vs. FREQUENCY
ZERO-CURRENT COMPARATOR THRESHOLD
vs. TEMPERATURE
5.35
ZCP THRESHOLD (mV)
20
15
10
5
0
-5
MAX5058/59 toc22
25
GAIN (dB)
5.40
MAX5058/59 toc21
30
5.30
5.25
5.20
5.15
5.10
-10
5.05
-15
5.00
-20
0.01
0.1
1
10
100
FREQUENCY (Hz)
8
1k
10k
100k
FREQUENCY (Hz)
25.1
MAX5058/59 toc19
VCSP = 100mV
0
CSA INPUT OFFSET
vs. TEMPERATURE
CURRENT-SENSE AMPLIFIER (CSA) GAIN
vs. TEMPERATURE
20.04
MAX5058/59 toc18
5.6
0.015
GAIN (dB)
fSW = 250kHz
RSA GAIN
vs. FREQUENCY
MAX5058/59 toc17
5.8
REMOTE-SENSE AMPLIFIER (RSA) GAIN
vs. TEMPERATURE
MAX5058/59 toc16
6.0
IV+ (mA)
MAX5058/MAX5059
Parallelable Secondary-Side Synchronous Rectifier
Driver and Feedback-Generator Controller ICs
-40 -25 -10 5 20 35 50 65 80 95 110 125
TEMPERATURE (°C)
_______________________________________________________________________________________
1M
10M 100M
Parallelable Secondary-Side Synchronous Rectifier
Driver and Feedback-Generator Controller ICs
70
65
60
33.4
33.2
33.0
32.8
32.6
MAX5058/59 toc25
33.6
1.60
1.59
ADJUSTMENT RANGE (µA)
75
SFP = +2.5V
SFN = 0V
33.8
MAX5058/59 toc24
80
34.0
SFA SINK CURRENT (µA)
10mV OVERDRIVE
1.58
1.57
1.56
1.55
1.54
1.53
32.4
1.52
55
32.2
1.51
50
32.0
1.50
-40 -25 -10 5 20 35 50 65 80 95 110 125
-40 -25 -10 5 20 35 50 65 80 95 110 125
-40 -25 -10 5 20 35 50 65 80 95 110 125
TEMPERATURE (°C)
TEMPERATURE (°C)
TEMPERATURE (°C)
BUFIN TO QREC HIGH-TO-LOW
PROPAGATION DELAY vs. TEMPERATURE
60
58
56
54
52
50
48
46
44
42
40
38
36
34
32
30
MAX5058/59 toc27
PROPAGATION DELAY (ns)
42
41
40
39
38
37
36
35
34
33
32
31
30
29
28
MAX5058/59 toc26
-40 -25 -10 5 20 35 50 65 80 95 110 125
-40 -25 -10 5 20 35 50 65 80 95 110 125
TEMPERATURE (°C)
TEMPERATURE (°C)
BUFIN TO QSYNC LOW-TO-HIGH
PROPAGATION DELAY vs. TEMPERATURE
BUFIN TO QSYNC HIGH-TO-LOW
PROPAGATION DELAY vs. TEMPERATURE
58
56
54
52
50
48
46
40
38
36
34
32
30
28
26
44
24
42
22
40
MAX5058/59 toc29
MAX5058/59 toc28
60
PROPAGATION DELAY (ns)
PROPAGATION DELAY (ns)
BUFIN TO QREC LOW-TO-HIGH
PROPAGATION DELAY vs. TEMPERATURE
PROPAGATION DELAY (ns)
ZCP TO QSYNC DELAY (ns)
85
MAX5058/59 toc23
90
CURRENT-ADJUST VOLTAGE TO CURRENTCONVERTER ADJUSTMENT RANGE
vs. TEMPERATURE
SFA AMPLIFIER MAXIMUM
SINK CURRENT vs. TEMPERATURE
ZERO-CURRENT PROPAGATION DELAY
vs. TEMPERATURE
20
-40 -25 -10 5 20 35 50 65 80 95 110 125
-40 -25 -10 5 20 35 50 65 80 95 110 125
TEMPERATURE (°C)
TEMPERATURE (°C)
_______________________________________________________________________________________
9
MAX5058/MAX5059
Typical Operating Characteristics (continued)
(V+ = +12V, GND = PGND = 0, VDR = VREG, CQSYNC = CQREC = 0, ZCP = ZCN = BUFIN = CSP = CSN = SFN = VSN = GND, VIREF =
VVSP = 1.785V, VCOMPS = 0.5V, CVREG = 2.2µF, CVP = 1µF, CCOMPS = 0.1µF, CSFP = 68nF, TA = +25°C, unless otherwise noted.)
MAX5058/MAX5059
Parallelable Secondary-Side Synchronous Rectifier
Driver and Feedback-Generator Controller ICs
Pin Description
PIN
NAME
1
ZCP
Zero-Inductor Current-Sense Comparator Input. The source voltage of the freewheeling FET (N4 in the Typical
Application Circuit) is sensed. The gate drive is terminated when this voltage becomes positive during a primary
power-OFF cycle.
2
ZCN
Zero-Inductor Current-Sense Comparator Negative Input
3
GND
Ground Connection
4
SFN
Negative Input of the Share-Force Amplifier. Connect the SFN inputs together from all the power-supply
secondaries, then connect to the load return terminal (isolated GND). Connect to GND when current sharing is not
used.
5
SFP
Positive Input of the Share-Force Amplifier. Connect the SFP pins together from all the power-supply secondaries.
Leave this pin unconnected when current sharing is not used.
6
FUNCTION
COMPS Compensation Output of the Load-Share Transconductance Amplifier
7
TSF
Thermal Warning Flag Output
8
MRGU
Margin-Up Logic Input. When toggled high, the power-supply output voltage is set to the high margin.
9
MRGD
Margin-Down Logic Input. When toggled high, the power-supply output voltage is set to the low margin.
10
RMGD
Resistor Connection for Margin-Down
11
RMGU
Resistor Connection for Margin-Up
12
IREF
Reference Current Output. A resistor from this current source output to GND sets the reference voltage used by
the error amplifier.
13
COMPV
Compensation Connection for the Error Amplifier. The feedback optocoupler LED is also connected to this point.
This open-drain output is capable of sinking at least 5mA.
14
INV
Inverting Input of the Error Amplifier. A voltage-divider connected to this input scales the power-supply output
voltage for regulation.
15
VSO
Output of the Remote-Sense Amplifier
16
VSN
Negative Input of the Remote-Sense Amplifier. Connect this to the negative terminal of the load.
17
VSP
Positive Input of the Remote-Sense Amplifier. Connect this to the positive terminal of the load.
18
CSO
Output of the Current-Sense Amplifier. It can be used to monitor the output current.
19
CSN
Connect this input to the negative terminal of the output current-sense resistor. Connect to GND when not used.
20
CSP
Connect this input to the positive terminal of the output current-sense resistor. Connect to GND when not used.
21
VP
Compensation Pin for Internal +4V Preregulator. A minimum 1µF low-ESR capacitor must be connected to this pin
for bypassing.
22
V+
Supply Connection for the IC and Input to the Internal 5V (MAX5058) or 10V (MAX5059) Regulator. Maximum
voltage on this input is 28V.
23
VREG
Regulated +5V (MAX5058) or +10V(MAX5059) Output Used by the Internal Circuitry and the Output Drivers. A
minimum 1µF capacitor must be connected to this pin for bypassing.
24
BUFIN
Input for the Synchronizing Pulse. This pulse is provided by the primary-side power IC.
25
VDR
Supply Connection for the Output Drivers. Can be connected to VREG for 5V (MAX5058) or 10V (MAX5059)
operation.
26
QREC
Driver Output for the Rectifying MOSFET
27
PGND
Power-Ground Connection. Return ground connection for the gate-driver pulse currents.
28
—
10
QSYNC Driver Output for the Recirculating MOSFET
EP
Exposed Pad. This is the exposed pad on the underside of the IC. Connect the exposed paddle to GND and to a
large copper ground plane to aid in heat dissipation.
______________________________________________________________________________________
Parallelable Secondary-Side Synchronous Rectifier
Driver and Feedback-Generator Controller ICs
MAX5058/MAX5059
MARGINING BLOCK
MRGU
MAX5058/MAX5059
8
REGULATOR AND THERMAL MANAGEMENT BLOCK
50kΩ
UVLO AND
THERMAL
SHUTDOWN
SD DRIVERS
MRGD
9
22 V+
LDO
5V/10V
PREG
4V
21 VP
23 VREG
50kΩ
7
TSF
5
SFP
4
SFN
+125°C FLAG
RMGD 10
QMD
R
CURRENT-SHARE BLOCK
R
RMGU 11
SFA
QMU
R
R
ERROR AMPLIFIER BLOCK
COMPV 13
INV 14
V TO I
CAA
42mV
X2
10 CSN
REFERENCE CURRENT BLOCK
COMPS
20 CSP
0.5V
I = (1.15 x (VCAA - 1.25))µA
VCAA ≥ 1.25V
IREF
50µA
IREF 12
X1
500µS
E/A
6
18 CSO
REMOTE-SENSE AMPLIFIER BLOCK
VSO 15
VSN 16
X1
RSA
VSP 17
GATE-DRIVER BLOCK
25 VDR
BUFIN 24
ZCP
26 QREC
1
20ns
5mV
28 QSYNC
ZCN
2
GND
3
27 PGND
20ns
30ns FALLING
EDGE DELAY
SD DRIVERS
Figure 1. MAX5058/MAX5059 Functional Diagram
______________________________________________________________________________________
11
MAX5058/MAX5059
Parallelable Secondary-Side Synchronous Rectifier
Driver and Feedback-Generator Controller ICs
Detailed Description
The MAX5058/MAX5059 enable the design of high-efficiency, isolated power supplies using synchronous rectification on the secondary side. These devices
commutate the secondary-side MOSFETs by providing
a clean gate-drive signal that is synchronized to the
power MOSFET switching in the primary side of the isolation transformer. Once fully enhanced, the secondaryside MOSFETs have very low on-resistance, producing
a voltage drop much lower than Schottky diodes, resulting in much higher efficiencies. Simultaneous conduction of the synchronous rectifier MOSFETs is avoided by
having a look-ahead signal before the primary
MOSFETs turn on. This eliminates large current spikes
from a shorted transformer secondary.
The MAX5058 has a 5V internal gate-drive voltage regulator that can be used with logic-level MOSFETs. The
MAX5059 has a 10V internal gate-drive voltage regulator that can be used with high-gate-voltage MOSFETs.
In addition to the gate drivers, there are blocks that
make the MAX5058/MAX5059 complete secondaryside solutions. These blocks are as follows:
• Regulator and thermal-management block
• Buffer input and gate-driver block
• Reference-current block
• Error-amplifier block
• Margining block
• Remote-sense amplifier block
• Current-share block
Regulators and Thermal Management
The linear regulators in the MAX5058/MAX5059 provide
power for the internal circuitry, as well as power for running the external synchronous MOSFETs. Design is simplified by deriving the power from the secondary
winding before the output-filter inductor. The peak voltage at the secondary is at least twice the output voltage, yielding more than 7V peak even for output
voltages down to 3.3V. Use a diode and a capacitor to
rectify and filter the voltage before applying it to V+ (see
D6 and C32 in the Typical Application Circuit). The
input for the regulator is V+ and the output is VREG.
Connect VDR to VREG to provide the supply for the gate
driver’s QREC and QSYNC. For logic-level MOSFETs,
use the MAX5058. For conventional MOSFETs that
require 10V to be fully enhanced, use the MAX5059.
The V+ input voltage range is from +4.5V to +28V.
Supply enough current to this input to satisfy the quies-
12
cent supply current of the MAX5058/MAX5059, as well
as the current for the MOSFET drivers. Estimate the total
required supply current by using the following formula:
IV + = ISW + fSW × (QN3 + QN4 )
where IV+ is the current that must be supplied into V+
and QN3, QN4 are the total gate charges of MOSFETs
N3 and N4 in the Typical Application Circuit. fSW is the
switching frequency and ISW is the switching current of
the part. Use high-quality ceramic capacitors to bypass
V+ and VREG. Use additional capacitance as required
for bypassing switching currents generated by the drivers when driving the chosen MOSFETs. Connect at
least a 1µF ceramic capacitor at the output of the regulator VREG for stability.
The MAX5058/MAX5059 have an exposed pad at the
back of the package to enable heatsinking directly to a
ground plane. When soldered to a 1in2 copper island,
these devices are able to dissipate approximately 1.9W
at +70°C ambient temperature. Connect the exposed
pad to the GND.
In addition to the regulators, this block contains a thermal-shutdown circuit that shuts down the gate drivers if
the die temperature exceeds +160°C. This is a last
resort shutdown mechanism. The trigger of this shutdown mechanism must be avoided. Turning off the
secondary synchronous rectifier drivers in this manner
while the output carries the full load current causes the
current to be diverted to the lossy external diodes or
body diodes of the MOSFETs. This, in most cases,
leads to rectifier failure due to power dissipation. To
prevent this, make use of the TSF output (temperature
warning flag). TSF is an open-drain output that gets
asserted when the die temperature exceeds +125°C,
well before the actual thermal shutdown at +160°C. An
optocoupler connected from VREG to the TSF pin can
provide a means for shutting down the switching at the
primary side, thus avoiding catastrophic failure.
Buffer Input (BUFIN) and MOSFET Drivers
The MAX5058/MAX5059 drive external N-channel
MOSFETs at QSYNC and QREC. The QSYNC output
drives the gate of the freewheeling MOSFET N4 in the
Typical Application Circuit. The QREC output drives the
gate of the rectifying MOSFET N3 in the Typical
Application Circuit. Each gate-driver output is capable
of sinking and sourcing up to 2A peak current,
enabling the MAX5058/MAX5059 to drive high-gatecharge MOSFETs.
______________________________________________________________________________________
Parallelable Secondary-Side Synchronous Rectifier
Driver and Feedback-Generator Controller ICs
When BUFIN goes high, QREC goes high and QSYNC
goes low. When BUFIN goes low, QREC goes low and
QSYNC goes high.
The MAX5058/MAX5059 provide improved efficiency at
light loads by allowing discontinuous conduction operation. A zero-crossing comparator with inputs ZCP and
ZCN monitors the current through the freewheeling
MOSFET using a sense resistor at its source. The freewheeling MOSFET is turned off when the inductor current is near zero. The actual threshold can be externally
adjusted. The Typical Application Circuit shows one
method for trip-point adjustment using components
R31 and R34.
BUFIN is internally clamped to 4V. Use a voltage-divider,
if necessary, to reduce any external voltage applied to
this pin to less than 4V.
MAX5042
MAX5043
MAX5058
REG5
BSS84
PPWM
VREG (5V)
560Ω
330Ω
BUFIN
2kΩ
PS9715
OR EQUIVALENT
HIGH-SPEED
OPTOCOUPLER
PWMNEG
GND
Figure 2. Interface of MAX5058 to MAX5042/MAX5043 Using a High-Speed Optocoupler
MAX5042
MAX5043
MAX5059
3.10kΩ
MMBT3904
REG5
PPWM
VREG (10V)
BSS84
560Ω
330Ω
BUFIN
2kΩ
PWMNEG
PS9715
OR EQUIVALENT
HIGH-SPEED
OPTOCOUPLER
1µF
4.42kΩ
GND
Figure 3. Interface of MAX5059 to MAX5042/MAX5043 Using a High-Speed Optocoupler
______________________________________________________________________________________
13
MAX5058/MAX5059
The MOSFET drivers are synchronized to the primaryside switching by using the BUFIN input. BUFIN
accepts the PWM information from the primary through
a high-speed optocoupler or through a small isolation
pulse transformer. Figures 2 through 6 show the interface details using an optocoupler or a pulse transformer with two different kinds of primary-side PWM
controllers.
For proper operation, the MAX5051, MAX5042, and
MAX5043 devices generate a look-ahead signal that
precedes the actual switching of the primary MOSFETs
by a small amount of time, typically less than 100ns.
Additional circuitry may be required when the
MAX5058/MAX5059 are used with other primary-side
controllers not capable of providing a look-ahead signal.
MAX5058/MAX5059
Parallelable Secondary-Side Synchronous Rectifier
Driver and Feedback-Generator Controller ICs
4.7Ω
MAX5051
MAX5058
REG5
LXVDD
BSS84
LXH
VREG (5V)
560Ω
330Ω
BUFIN
1µF
2kΩ
2kΩ
PS9715
OR EQUIVALENT
HIGH-SPEED
OPTOCOUPLER
GND
GND
Figure 4. Interface of MAX5058 to MAX5051 Using a High-Speed Optocoupler
4.7Ω
MAX5051
MAX5059
REG5
3.10kΩ
MMBT3904
LXVDD
VREG (10V)
BSS84
LXH
560Ω
330Ω
BUFIN
1µF
2kΩ
2kΩ
1µF
PS9715
OR EQUIVALENT
HIGH-SPEED
OPTOCOUPLER
GND
4.42kΩ
GND
Figure 5. Interface of MAX5059 to MAX5051 Using a High-Speed Optocoupler
MAX5051
MAX5058
MAX5059
4.7Ω
REG5
LXVDD
1µF
D1
T1
LXH
1N4148
301Ω
BUFIN
2kΩ
LXL
GND
D2
GND
T1: PULSE ENGINEERING, PE-68386
D1, D2: CENTRAL SIMICONDUCTOR, CMOSH-3
Figure 6. Interface Circuit to MAX5051 Using a Pulse Transformer
14
______________________________________________________________________________________
Parallelable Secondary-Side Synchronous Rectifier
Driver and Feedback-Generator Controller ICs
When the inductor current is allowed to become discontinuous, the loop dynamics change and the circuit
must be compensated accordingly to accommodate
stable continuous and discontinuous mode operation.
Turning off the freewheeling MOSFET is accomplished
by using the zero-current comparator (pins ZCP and
ZCN). Use this comparator to sense reverse current in
the freewheeling MOSFET and turn off the device by
pulling QSYNC low. An internal latch prevents the freewheeling MOSFET from turning on until the off-time of
the next cycle.
connected from IREF to GND. INV is the inverting input
and connects to the center of a resistive divider from
OUT to INV to GND. The output of the error amplifier,
COMPV, connects to the cathode of the LED in the
optocoupler to control the diode current that transmits
the error signal back to the primary-side controller. An
open-drain-output error amplifier simplifies interfacing
with the feedback optocoupler. Use this error amplifier
the same way as the industry-standard TL431 shunt reference. The open-drain output provides flexibility that
may be necessary when additional functionality such
as secondary current-limit regulation is required. Unlike
the TL431, the output of the internal error amplifier of
the MAX5058/MAX5059 is guaranteed to be a maximum of 200mV with a 5mA drain current, compared to
2.5V for the TL431 and 1.24V for the TLV431.
In some cases, it is possible to avoid the use of the output voltage-divider (R1 and R2) by connecting INV to
the output through just R1. This eliminates the voltage
tolerance errors caused by R1 and R2. Output voltage
in this configuration is set directly by using a suitable
resistor at IREF. Figure 7 shows this configuration.
VOUT
Reference Current
R1
The MAX5058/MAX5059 do not have an explicit reference voltage generator. Instead, they contain a 1%accurate trimmed 50µA current source. This allows significant flexibility in setting the reference voltage. In
some cases, the output-voltage resistive divider, consisting of R1 and R2 in the Typical Application Circuit,
can be eliminated by selecting a suitable resistor value
at the IREF pin. This reduces the error that the output
voltage-divider may add. Use a low-value bypass
capacitance at this pin to eliminate noise. Typical values
for this capacitance are calculated by considering the
pole that it presents with R12. This pole must be placed
well beyond the frequency range of interest of the current-share loop. Use values less than 2.2nF.
Error Amplifier
The MAX5058/MAX5059 incorporate a 1.3MHz unity
gain-bandwidth error amplifier with inputs INV, IREF,
and output COMPV. IREF is the noninverting input and
also serves as the reference voltage generator with the
internal 50µA current source and the external resistor
COMPV
13
C28
INV
14
E/A
VOUT = (50µA) x R12
FOR: 0.5V ≤ VOUT ≤ 2.5V
IREF
50µA
IREF
12
R12
Figure 7. Output Voltage Regulation for 0.5V ≤ VOUT ≤ 2.5V
______________________________________________________________________________________
15
MAX5058/MAX5059
Reverse-Current Prevention
in Synchronous Rectifiers
One benefit of secondary-side synchronous rectification is increased efficiency. Another benefit is that it
allows the inductor current to remain continuous
throughout the operating load range. This results in
constant loop dynamics that are easy to compensate.
In some cases, it may be necessary to turn off the freewheeling MOSFET when the current through this device
attempts to flow from drain to source. Turning off this
MOSFET can be done to enhance efficiency at low output current. When multiple power supplies are paralleled, the power supply with the highest output voltage
has a tendency to source current into the power-supply
outputs with lower output voltage. Turning off the freewheeling MOSFET also prevents this current back-flow.
MAX5058/MAX5059
Parallelable Secondary-Side Synchronous Rectifier
Driver and Feedback-Generator Controller ICs
VOUT > 2.5V
C27
R19
R12
Figure 9 shows a typical configuration with an optocoupler for output voltages lower than 2.5V. In this case,
the direct connection of the optocoupler to the output is
not possible. There is only one feedback path and the
error-amplifier feedback network must be designed
accordingly.
Figure 10 shows the simplified block diagram for the
error amplifier.
R12
COMPV
13
Figure 8 shows a typical configuration with output voltages high enough (V OUT > 2.5V) to allow a typical
optocoupler to be fully biased. In this case, there are
two feedback paths—one though the error amplifier
and one through the output-connected optocoupler.
This second feedback path must be considered when
compensating the overall feedback loop.
C28
INV
14
E/A
Voltage Margining
IREF
12
IREF
50µA
R12
Figure 8. Optocoupler Connection for VOUT > 2.5V
VREG
(PIN 23)
0.5V < VOUT < 2.5V
C27
R19
Rff
COMPV C28
13
Rf
R1
INV
14
Cf
The margining inputs MRGU (margin up) and MRGD
(margin down) control two internal MOSFETs with opendrain outputs at RMGU and RMGD, respectively. When
margining is used, connect two pullup resistors from
RMGU and RMGD to I REF . A logic-high voltage at
MRGU causes QMU (see Figure 1) to open, increasing
the equivalent resistance at IREF and the reference voltage (VIREF). The error-amplifier inverting input, INV,
tracks IREF and forces the primary-side controller to
increase the output voltage. MRGD has the opposite
effect. When a logic high is applied to MRGD, QMD
turns on, decreasing the equivalent resistance at IREF
and effectively reducing VIREF. This causes INV to track
and force the primary-side controller to reduce the output voltage.
The margining inputs MRGU and MRGD are internally
pulled to GND with 40kΩ resistors. When margining is
not used, the inputs can be left floating or connected to
GND to make VIREF = 50µA × R12.
Calculation Procedure for Output-Voltage Setting
Resistors and Margining
Use the following step-by-step procedure to calculate
the output-voltage setting and margining resistors (see
the Typical Application Circuit):
E/A
IREF
50µA
INV
14
IREF
12
IREF
R12
Figure 9. Optocoupler Connection for VOUT < 2.5V
16
12
Figure 10. Simplified Error-Amplifier Diagram
______________________________________________________________________________________
COMPV
13
Parallelable Secondary-Side Synchronous Rectifier
Driver and Feedback-Generator Controller ICs
∆D = 5%
6) Recalculate Req with the selected values:
Req =
3) Calculate R32:
R32 = Req ×
Req = 35.24kΩ.
7) Calculate R33:
100% + ∆U
∆U
R32 = 743.4kΩ.
Calculated
Select the nearest 0.1% value.
Selected
R32 = 741kΩ.
4) Calculate R12:
R33 =
100% × Req × R12
R12 × (100% + ∆D) - 100% × Req
R33 = 361.186kΩ.
Select the nearest 0.1% value:
R
× ∆U
R12 = 32
100%
Calculated
R33 = 361kΩ.
Selected
8) Calculate the reference voltage with the selected
chosen values:
VIREF = 50µA ✕ Req.
Req from step 6.
VIREF = 1.762V.
R12 = 37.05kΩ.
Calculated
Select the nearest 0.1% value.
R12 = 37kΩ.
R12R32
R12 + R32
Selected
VOUT
COMPV
13
C28
VSP
17
VSO
15
INV
14
E/A
RSA
VSN
16
VOUT = (50µA) x R12
FOR: 0.5V ≤ VOUT ≤ 2.5V
IREF
50µA
IREF
12
R12
Figure 11. Remote-Sense Amplifier Connection for 0.5V ≤ VOUT ≤ 2.5V
______________________________________________________________________________________
17
MAX5058/MAX5059
5) Select the margin-down percentage value:
1) Select a parallel equivalent resistance Req value to
produce the nominal reference voltage. For example, Req = 35.4kΩ gives you VIREF = 1.77V.
2) Select the margin-up percentage value:
∆U = 5%
MAX5058/MAX5059
Parallelable Secondary-Side Synchronous Rectifier
Driver and Feedback-Generator Controller ICs
VOUT
R1
R2
COMPV
13
C28
VSP
17
VSO
15
INV
14
RSA
VSN
16
E/A
R1
VOUT = 1 + R2
(
IREF
IREF
50µA
12
)
✕
VIREF
VIREF = (50µA) ✕ R12
R12
Figure 12. Remote-Sense Amplifier Connection for VOUT > 2.5V (or any Other Arbitrary Voltage)
9) Select a value for R1 and calculate R2 for VOUT =
3.3V:
R1 = 19.1kΩ
R2 =
VIREF
R1
VOUT - VIREF
11 shows this configuration. Figure 12 shows the use of
the remote-sense amplifier with a voltage-divider. The
remote-sense amplifier has an input bias current of
100µA. The impedance of R1 and R2 must be kept low
in this configuration to avoid excessive errors in the output-voltage set point.
Current Sharing
R2 = 21.882kΩ.
Select the nearest 1% value.
R2 = 21.8kΩ.
When margining is not used, substitute R12 for Req
in step 8 and go to step 9.
Remote-Sense Amplifier
Use the remote-sense amplifier (RSA in Figure 1) to
directly sense the voltage across the load, compensating for voltage drops in PC board tracks or load connection wires. The remote-sense amplifier is a
unity-gain amplifier with sufficient bandwidth to not
interfere with the normal operation of the voltage-control loop. Direct sensing of the output voltage is possible if the output voltage is between 0.5V to 2.5V. Figure
18
When multiple power modules are providing power to
the same load, the load current must be shared equally
to provide the best reliability and thermal distribution.
The MAX5058/MAX5059 contain circuitry that enable
current sharing among paralleled power supplies without requiring an explicit controlling master circuit.
Current sharing is accomplished by connecting together the current-share bus pins (SFP and SFN) of all paralleled power supplies (see Figure 13), thus creating a
current-force/share bus. The voltage level on this differential bus is proportional to the output current of the
power supply that has the highest current compared to
the other supplies. The number of power supplies that
can be paralleled with this method is limited only by
practical considerations.
______________________________________________________________________________________
Parallelable Secondary-Side Synchronous Rectifier
Driver and Feedback-Generator Controller ICs
MRGD
MAX5058/MAX5059
MRGU
CSN
POWER MODULE
CSP
VIN+
VOUT+
VIN-
MAX5051
MAX5058
VSP
OR
VSN
AND
SYNCIN
VOUT-
MAX5059
STARTUP
SYNCOUT
SFN
SFP
MRGU
MRGD
CSN
POWER MODULE
CSP
VIN+
36V TO 72V
VIN+
VIN-
VIN-
VOUT+
MAX5051
MAX5058
VSP
OR
VSN
AND
SYNCIN
LOAD
VOUT-
MAX5059
STARTUP
SYNCOUT
SFN
SFP
MRGU
MRGD
CSN
POWER MODULE
CSP
VIN+
VOUT+
VIN-
MAX5058
MAX5051
AND
VSN
OR
SYNCIN
STARTUP
VSP
VOUT-
MAX5059
SYNCOUT
SFN
SFP
Figure 13. Paralleling Multiple Power-Supply Modules for Current Sharing
When the MAX5051 is used as the primary-side controller, additional benefits are also realized with its special paralleling pins. The MAX5051 allows simultaneous
shutdown and wake-up, as well as frequency synchronization and 180 degree out-of-phase operation of
each connected primary.
The current-share loop consists of the following functional blocks:
•
A diode ORed force amplifier that connects with the
other modules and forces the bus to carry a voltage
proportional to the highest current among the modules.
•
A sense amplifier that senses this share-bus voltage and applies it to internal circuitry.
•
A fixed gain of 20, current-sense amplifier that
senses the output current through a sense resistor.
•
A current-adjust amplifier that functions as an erroramplifier block in the current-share loop.
•
A voltage-to-current (VtoI) block that adds a small
amount of current to the reference current, increasing the reference voltage and enabling the module
to share more current.
______________________________________________________________________________________
19
MAX5058/MAX5059
Parallelable Secondary-Side Synchronous Rectifier
Driver and Feedback-Generator Controller ICs
Current-sharing functions follow:
The voltage across the current-sense resistor for each
module is sensed and compared to the voltage on the
current-share bus. The voltage on the current-share bus
represents the current from the module that has the highest output current compared to the other modules. Each
module compares its current to this maximum current. If
its current is less than the maximum, then the module
increases its reference current with the VtoI block. This
raises the reference voltage presented at the noninverting input of the error amplifier. With a higher reference
voltage, the output voltage of the module rises in an
attempt to increase its output current. This process continues until the currents balance between the modules.
The current-adjust amplifier (see Figure 1) has an offset
at its inverting input that requires the share-bus voltage
to reach 40mV before the current-share control loop
attempts to regulate the output-load-current balance.
Thus, the current-share regulation does not begin until
the current-sense signals have exceeded 2mV (i.e.,
42mV/20).
V TO I
1.5µA
SLOPE = 1.15µA/V
VCAA
1.25V
Figure 14. Transfer Function Curve of the V to I Block
FEEDBACK
NETWORK
PWM STAGE
AND FILTERS
E/A
VOUT
RS
+ VSENSE -
GPS (s)
RLOAD
GCSA (s)
GV TO I (s)
GCAA (s)
CAA
V TO I
RIREF
CSA
CCOMPS
Figure 15. Small-Signal Equivalent Current-Share Control Loop
The adjustment range and thus the sharing capability of
the modules is limited by the amount of additional output voltage boost possible through the VtoI block. The
typical voltage boost is +3% (i.e., 1.5µA/50µA). Figure
14 shows the transfer function of the VtoI block. This
adjustment range also sets a limit on the amount of voltage drop allowed for current sharing. For effective current sharing, the sum of all voltage drops must be kept
below 3% and the output-to-load connection drop of
each power module must be kept equal.
20
Figure 15 shows the simplified equivalent small-signal
circuit of the current-share control loop. The currentadjust amplifier represents the error amplifier in this
loop. The command signal, which is the voltage across
the SFP and SFN pins, is applied to the noninverting
input of this amplifier. For small-signal analysis, the
noninverting pin is shown grounded in Figure 15. This is
a low-bandwidth loop.
Assuming a much smaller unity-gain crossover bandwidth
(fCS) for the current-share loop compared to the main output-voltage-regulation loop (i.e., fCS << fC), the open-loop
gain of the current-share loop can be written as:
 GCAA (s) 
GT (s) = GSFA (s) × 
 × (GVtoI(s) × RIREF )
 s × CCOMPS 
× GPS (s) ×
RS
RS + RLOAD
where fCS is the unity-gain crossover frequency of the
current-share loop (typically 10Hz to 100Hz), fC is the
unity-gain crossover frequency of the main output loop,
GPS(s) is the gain of the power stage from the reference voltage input of the error amplifier to the output
(GPS = VOUT/VIREF), RS is the current-sense resistor,
and RLOAD is the load resistance. Note that the currentshare loop bandwidth is highest for the lowest value of
RLOAD (maximum load).
______________________________________________________________________________________
Parallelable Secondary-Side Synchronous Rectifier
Driver and Feedback-Generator Controller ICs
90
GAIN (dB/DIV)
10
45
PHASE
GAIN
5
0
0
-5
-10
PHASE (DEGREES/div)
15
CCOMPS =
-45
-15
-20
-90
1
10
100
1k
10k
FREQUENCY (Hz)
Figure 16. Idealized (with Ideal Power Stage and Optocoupler)
Frequency Response (GPS(s)) from Noninverting Input of the
Error Amplifier to the Output of the Power Supply for the
Typical Application Circuit of Figure 18
80
40
90
20
45
0
0
-20
-45
GAIN
-40
-90
-60
-135
-80
-180
1
10
100
1k
PHASE (DEGREES/div)
135
PHASE
(36.61µF × Hz / V) × RS × VOUT
fCS × (RS + RLOAD )
The current-sharing loop is compensated with a capacitor from COMPS to GND. This results in a dominant
pole that forces the loop gain of the current-share loop
to cross 0dB with a single pole (20dB/decade) rolloff.
When RLOAD >> RS, the above can be simplified further.
CCOMPS =
(36.61µF × Hz / V) × RS × VOUT
fCS × RLOAD
Example:
RS = 2mΩ
VOUT = 3.3V
180
60
GAIN (dB/DIV)
Equating |GT| = 1 and solving for CCOMPS yields:
10k
FREQUENCY (Hz)
Figure 17. Overall Open-Loop Response of the Current-Share
Loop
Figure 16 shows the idealized small-signal response of
the Typical Application Circuit from the noninverting
input of the error amplifier to the output. This response
shows that the unity-gain crossover frequency of the
current-share loop can easily be placed between 10Hz
and 100Hz, while at the same time avoiding interaction
with the main voltage-control loop.
For frequencies below 100Hz, GT(s) can be written as
(using the DC gain value for GPS(s)):
fCS = 10Hz
RLOAD = 0.22Ω
CCOMPS =
(36.61µF × Hz / V) × (0.002Ω) × (3.3V)
(10Hz) × (0.22Ω)
≅ 0.11µF
The resulting overall open-loop response of the currentshare control loop is shown in Figure 17.
Applications Information
Isolated 48V Input Power Supply
Figure 18 shows a complete design of an isolated synchronously rectified power supply with a +36V to +75V
telecom input voltage range. This design uses the
MAX5051 as the primary-side controller and the
MAX5058 as the secondary-side synchronous rectifier
driver. Figures 19 though 24 show some of the performance aspects of this power-supply design. This
power supply can sustain a continuous short circuit at
its output terminals. This circuit is available as a completely built and tested evaluation kit (MAX5058EVKIT).
______________________________________________________________________________________
21
MAX5058/MAX5059
(500µS) × 1.15µA / V × R
(
) IREF
s × CCOMPS
V
RS
× OUT ×
VIREF RS + RLOAD
GT (s) = 20 ×
POWER-STAGE GAIN/PHASE
20
22
D8
C17
0.33µF
R11
360Ω
R3
2.2kΩ
REG5
LXL
LXH
R27
10Ω
LXVDD
C18
1000pF
3
4
14
13
12
11
10
9
8
7
6
5
4
3
2
1
U2
REG9
PVIN
REG9
REG5
C26
0.1µF
C19
1µF
C6
0.1µF
C4
4.7µF
R15
31.6kΩ
1%
C5
4700pF
C2
390pF
TP5
C1
100pF
C3
4.7µF
R16
10.5kΩ
1%
R25
100kΩ
R21
24.9kΩ
1%
REG5
C24
1000pF
+VIN
REG5
LXL
LXH
2
1
LXVDD
STT
PVIN
REG9
REG5
FB
COMP
CSS
CON
RCFF
SYNCOUT
RCOSC
C27
0.15µF
OPTO_CAT
R19
475Ω
CS
DRVL
PGND
DRVDD
DRVB
XFRMRH
DRVH
BST
AVIN
IC_PADDLE
MAX5051
U1
GND
UVLO
STARTUP
FLTINT
SYNCIN
VOUT
29
15
16
17
18
19
20
21
22
23
24
25
26
27
28
TP6
C8
4.7µF
D1
C9
1µF
DRVB
Figure 18. Schematic of a +48V Input, 3.3V at 15A Output, Synchronous Rectified, Isolated Power Supply
______________________________________________________________________________________
LXL
LXVDD
LXH
C31
0.1µF
C22
2200pF
2kV
+VIN
XFRMRH
C20
220pF
REG9
+VIN
ON/OFF
C7
0.22µF
D7
D9
R14
270Ω
R9
8.2Ω
R8
8.2Ω
R7
0Ω
R4
1MΩ
1%
R35
0Ω
6
5
3
1
R17
0.027Ω
1%
4
D3
1
T2
C21
4.7µF
80V
PVIN
N2
3
2
7
8
C34
330pF
4
6
D10
R22
15kΩ
R18
4.7Ω
D5
R13
47Ω
R6
R5
1MΩ 38.3kΩ
1%
1%
REG9
+VIN
6
1
5
2
3
R28
301Ω
1%
+VIN
4T
8T
T1
1
2
10
2T
8
XFRMRH
D2
XFRMRH
3
2
8
7
R30
2kΩ
1%
4
N1
D6
6
7
1
6
5
4
N3
1
7
8
C16
3.3µF
C29
1µF
C35
1µF
3
N4
4
R26
0.002Ω
2
6
5
V+
VREG
V+
R24
10Ω
(CSP)
TP1
R27
10Ω
R38
10Ω
C39
220pF
R31
220Ω
1%
L1
2.4µH
C11
0.47µF
100V
VOUT (CSN)
C10
0.47µF
100V
VOUT
C30
1µF
C32
1µF
D4
C23
1000pF
R10
20Ω
5
8
C13
270µF
4V
24
25
23
22
21
20
19
18
17
16
26
2
1
BUF_IN
VDR
VREG
V+
VP
CSP
CSN
CSO
VSP
VSN
+VIN
VDD = 3V
RL = 16Ω
fIN = 10kHz
PGND
GND
SFN
SFP
COMPS
TSF
MRGU
MRGD
RMGD
RMGU
IREF
COMPV
29
27
3
4
5
6
7
8
9
10
11
12
13
VSO
14
INV
15
C15
270µF
4V
(CSP)
2
N5
3
IC_PADDLE
MAX5058
U3
QSYNC
28
VREG
C14
270µF
4V
C25
0.047µF
100V
QREC
ZCN
ZCP
R34
220Ω
C12
1µF
100V
+VIN
C36
1µF
R33
340kΩ
0.5%
R23
10Ω
TP2
TP8
TPMU
C37
220pF
R12
34.8kΩ
0.5%
OPTO_CAT
TPMD
C28
0.047µF
SGND
R20
0.004Ω
1%
TP7
R2
19.1kΩ
1%
R1
19.1kΩ
1%
VOUT
DRVB
C38
0.068µF
TP3
R36 VOUT (CSN)
0.004Ω
1%
R29
1Ω
XFRMRH
R32
698kΩ
0.5%
C33
1µF
10V
1
-VIN
MAX5058/MAX5059
Parallelable Secondary-Side Synchronous Rectifier
Driver and Feedback-Generator Controller ICs
Typical Application Circuit
Parallelable Secondary-Side Synchronous Rectifier
Driver and Feedback-Generator Controller ICs
8
90
7
POWER DISSIPATION (W)
R20 = R26 = R36 = 0Ω
EFFICIENCY (%)
85
80
75
70
65
6
5
4
3
2
1
R20 = R26 = R36 = 0Ω
0
60
0
2
4
6
8
10
12
0
14
Figure 19. Efficiency at Nominal 3.3V Output Voltage vs. Load
Current (48V Nominal Input Voltage)
RL = 0.22Ω
2
4
6
8
10
12
14
LOAD CURRENT (A)
LOAD CURRENT (A)
R20 = R26 = R36 = 0Ω
Figure 20. Power Dissipation at Nominal 3.3V Output Voltage
vs. Load Current (48V Nominal Input Voltage)
R20 = R26 = R36 = 0Ω
VOUT
100mV/div
VOUT
1V/div
ILOAD
5A/div
ILOAD
5A/div
4ms/div
Figure 21. Turn-On Transient at Full Load (Resistive Load)
VOUT
1ms/div
Figure 22. Output Voltage Response to Step Change in Load
Current (ILOAD from 50%, max to 75%, max)
______________________________________________________________________________________
23
MAX5058/MAX5059
95
MAX5058/MAX5059
Parallelable Secondary-Side Synchronous Rectifier
Driver and Feedback-Generator Controller ICs
R20 = R26 = R36 = 0Ω
R20 = R26 = R36 = 0Ω
ILOAD
10A/div
1ms/div
VOUT
50mV/div
ILOAD
10A/div
20ms/div
2µs/div
Figure 23. Output Voltage Ripple at +48V Nominal Input
Voltage and Full Load Current (Scope Bandwidth = 20MHz)
Pin Configuration
Figure 24. Load Current (10A/div) as a Function of Time when
the Converter Attempts to Turn On into a 50mΩ Short Circuit
Chip Information
TRANSISTOR COUNT: 1762
PROCESS: BiCMOS
TOP VIEW
ZCP 1
28 QSYNC
ZCN 2
27 PGND
GND 3
26 QREC
SFN 4
25 VDR
SFP 5
COMPS 6
MAX5058AUI
MAX5059AUI
24 BUFIN
23 VREG
TSF 7
22 V+
MRGU 8
21 VP
MRGD 9
20 CSP
RMGD 10
19 CSN
RMGU 11
18 CSO
IREF 12
17 VSP
COMPV 13
16 VSN
INV 14
15 VSO
TSSOP
CONNECT EXPOSED PADDLE TO GND.
24
______________________________________________________________________________________
Parallelable Secondary-Side Synchronous Rectifier
Driver and Feedback-Generator Controller ICs
TSSOP 4.4mm BODY.EPS
PACKAGE OUTLINE, TSSOP, 4.40 MM BODY
EXPOSED PAD
21-0108
C
1
1
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 ____________________ 25
© 2003 Maxim Integrated Products
Printed USA
is a registered trademark of Maxim Integrated Products.
MAX5058/MAX5059
Package Information
(The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information
go to www.maxim-ic.com/packages.)