MAXIM MAX13256

19-5847; Rev 0; 6/11
EVALUATION KIT AVAILABLE
MAX13256
36V H-Bridge Transformer
Driver for Isolated Supplies
General Description
The MAX13256 H-bridge transformer driver provides a
simple solution for making isolated power supplies up to
10W. The device drives a transformer’s primary coil with
up to 300mA of current from a wide 8V to 36V DC supply. The transformer’s secondary-to-primary winding ratio
defines the output voltage, allowing selection of virtually
any isolated output voltage.
The device features adjustable current limiting, allowing
indirect limiting of secondary-side load currents. The current limit of the MAX13256 is set by an external resistor. A
FAULT output asserts when the device detects an overtemperature or overcurrent condition. In addition, the device
features a low-power mode to reduce the overall supply
current to 0.65mA (typ) when the driver is not in use.
The device can be operated using the internal oscillator
or driven by an external clock to synchronize multiple
MAX13256 devices and precisely set the switching frequency. Internal circuitry guarantees a fixed 50% duty
cycle to prevent DC current flow through the transformer,
regardless of which clock source is used.
The device is available in a small 10-pin (3mm x 3mm)
TDFN package and is specified over the -40NC to +125NC
automotive temperature range.
Benefits and Features
SSimple, Flexible Design
8V to 36V Supply Range
Up to 90% Efficiency
Provides Up to 10W to the Transformer
Undervoltage Lockout
2.5V to 5V Compatible Logic Interface
Internal or External Clock Source
Adjustable Overcurrent Threshold
SIntegrated System Protection
Fault Detection and Indication
Overcurrent Limiting
Overtemperature Protection
SSaves Space on Board
Small 10-Pin TDFN Package (3mm x 3mm)
Applications
Power Meters
Isolated Fieldbus Interfaces
24V PLC Supply Isolation
Medical Equipment
Motor Controls
Ordering Information appears at end of data sheet.
Typical Operating Circuit
+24V
1µF
VDD
4.6kI
FAULT
EN
CLK
ST1
MAX13256
ITH
ST2
0.1µF ISOLATED
VOUT
RLIM
GND
For related parts and recommended products to use with this part, refer to: www.maxim-ic.com/MAX13256.related
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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.
MAX13256
36V H-Bridge Transformer
Driver for Isolated Supplies
ABSOLUTE MAXIMUM RATINGS
(Voltages referenced to GND.)
VDD, FAULT............................................................-0.3V to +40V
ST1, ST2.................................................... -0.3V to (VDD + 0.3V)
CLK, ITH, EN............................................................-0.3V to +6V
FAULT Continuous Current.............................................. Q50mA
ST1, ST2 Continuous Current......................................... Q850mA
Continuous Power Dissipation (TA = +70NC)
TDFN (Four-Layer Board)
(derate 24.4mW/NC above +70NC)..........................1951.2mW
TDFN (Single-Layer Board)
(derate 18.5mW/NC above +70NC)..........................1481.5mW
Operating Temperature Range......................... -40NC to +125NC
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)
TDFN (Four-Layer Board)
Junction-to-Ambient Thermal Resistance (BJA)...........41NC/W
Junction-to-Case Thermal Resistance (BJC)..................9NC/W
TDFN (Single-Layer Board)
Junction-to-Ambient Thermal Resistance (BJA)...........54NC/W
Junction-to-Case Thermal Resistance (BJC)..................9NC/W
Note 1: Package thermal resistances were obtained using the method described in JEDEC specification JESD51-7. For detailed
information on package thermal considerations, refer to www.maxim-ic.com/thermal-tutorial.
ELECTRICAL CHARACTERISTICS
(VDD = 8V to 36V, VEN = 0V, TA = -40NC to +125NC, unless otherwise noted. Typical values are at TA = +25NC.) (Note 2)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
36
V
6
9
mA
0.65
1.1
mA
1
1.5
DC CHARACTERISTICS
Supply Voltage Range
VDD
(Note 3)
Supply Current
IDD
VEN = 0V, VCLK = 0V, RLIM = 1000I,
ST1/ST2 not connected
Disable Supply Current
IDIS
VEN = 3.3V, VCLK = 0V
ROH
ST1 = ST2 = high, IST1, ST2 = +300mA,
RLIM = 1000I
ROL
ST1 = ST2 = low, IST1, ST2 = -300mA,
RLIM = 1000I
Driver Output Resistance
Undervoltage-Lockout Threshold
VUVLO
Undervoltage-Lockout Threshold
VUVLO_HYST
Hysteresis
VDD rising
8
I
5.9
0.6
1.0
6.3
6.9
300
V
mV
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MAX13256
36V H-Bridge Transformer
Driver for Isolated Supplies
ELECTRICAL CHARACTERISTICS (continued)
(VDD = 8V to 36V, VEN = 0V, TA = -40NC to +125NC, unless otherwise noted. Typical values are at TA = +25NC.) (Note 2)
PARAMETER
SYMBOL
ST1, ST2 Current Limit
ILIM
ST1, ST2 Leakage Current
ILKG
MIN
TYP
MAX
RLIM = 1000I
CONDITIONS
500
650
800
RLIM = 3010I
165
215
265
VEN = 3.3V, VCLK = 0V,
VST1 = VST2 = 0V or VDD
-1
+1
UNITS
mA
FA
LOGIC SIGNALS (CLK, EN, FAULT)
Input Logic-High Voltage
VIH
Input Logic-Low Voltage
VIL
Input Leakage Current
IIL
FAULT Output Logic-Low
Voltage
VOL
FAULT Leakage Current
ILKGF
2
V
0.8
V
+1
FA
IFAULT = 10mA
1
V
VFAULT = 36V, FAULT deasserted
10
FA
VCLK = VEN = 5.5V or 0V
-1
AC CHARACTERISTICS
Switching Frequency
fSW
VCLK = 0V, measured at ST1/ST2 outputs
255
CLK Input Frequency
fEXT
External clocking
200
ST1/ST2 Duty Cycle
DTC
Internal or external clocking
49
ST1/ST2 Rise Time
tRISE
ST1/ST2 Fall Time
Crossover Dead Time
425
700
kHz
2000
kHz
51
%
ST1/ ST2 = 20% to 80% of VDD, RL = 1kI,
CL = 50pF, Figure 1a
100
ns
tFALL
ST1/ST2 = 80% to 20% of VDD, RL = 1kI,
CL = 50pF, Figure 1a
100
ns
tDEAD
RL = 200I, Figure 1b
50
30
ns
Watchdog Timeout
tWDOG
20
32
55
Fs
Current-Limit Blanking Time
tBLANK
Figure 2
0.73
1.2
2.0
ms
Current-Limit Autoretry Time
tRETRY
Figure 2
23.4
38.4
64.0
ms
PROTECTION
Thermal-Shutdown Threshold
TSHDN
+160
NC
Thermal-Shutdown Hysteresis
TSHDN_HYS
10
NC
Note 2: All units are production tested at TA = +25NC. Specifications over temperature are guaranteed by design.
Note 3: If VDD is greater than 27V, see the Snubber section.
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MAX13256
36V H-Bridge Transformer
Driver for Isolated Supplies
Test Circuits/Timing Diagrams
ST1/ST2
ST1
CL
RL
RL
ST2
(A)
(B)
VDD
80%
80%
ST1
20%
20%
0V
VDD
tDEAD
tRISE
tFALL
ST2
0V
(C)
Figure 1. Test Circuits (A and B) and Timing Diagram (C) for Rise, Fall, and Dead Times
ILIM
IST1, ST2
50%
tBLANK
50%
tRETRY
50%
0mA
Figure 2. Timing Diagram for Current Limiting
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MAX13256
36V H-Bridge Transformer
Driver for Isolated Supplies
Typical Operating Characteristics
(VDD = 24V, TA = +25NC, unless otherwise noted.)
ST1/ST2 SWITCHING FREQUENCY
vs. TEMPERATURE
9
8
550
4
500
ILIM (mA)
5
450
400
3
2
200
CLK = GND
NO LOAD
100
300
0
500
800
1100
1400
1700
1400
1000
-40 -25 -10 5 20 35 50 65 80 95 110 125
2000
1800
2200
2600
EXTERNAL CLOCK FREQUENCY (kHz)
TA (°C)
RLIM (I)
NORMALIZED CURRENT-LIMIT
THRESHOLD vs. TEMPERATURE
ST1/ST2 OUTPUT-VOLTAGE LOW
vs. SINK CURRENT
ST1/ST2 OUTPUT-VOLTAGE HIGH
vs. SOURCE CURRENT
1.08
1.06
500
1.04
24.1
24.0
23.9
23.8
VOL (mV)
1.00
0.98
VOH (V)
400
1.02
300
0.94
23.7
23.6
23.5
200
0.96
3000
MAX13256 toc06
600
MAX13256 toc04
1.10
MAX13256 toc05
200
400
300
350
1
23.4
23.3
100
23.2
0.92
23.1
0
0
-40 -25 -10 5 20 35 50 65 80 95 110 125
0
100 200 300 400 500 600 700 800
100 200 300 400 500 600 700 800
ISOURCE (mA)
ISINK (mA)
TA (°C)
ISOLATED OUTPUT VOLTAGE
vs. LOAD CURRENT
FAULT OUTPUT-VOLTAGE LOW
vs. SINK CURRENT
30
MAX13256 toc07
400
350
300
VDD = 24V
1:1 TRANSFORMER
FULL-WAVE RECTIFIER
NO SNUBBER
29
28
27
VOUT (V)
250
200
150
MAX13256 toc08
0.90
VOL (mV)
ILIM
600
500
6
fSW (kHz)
IDD (mA)
7
700
MAX13256 toc02
600
MAX13256 toc01
10
CURRENT-LIMIT THRESHOLD
vs. RLIM
MAX13256 toc03
SUPPLY CURRENT
vs. EXTERNAL CLOCK FREQUENCY
26
25
24
23
100
22
50
21
20
0
0
2
4
6
ISINK (mA)
8
10
0
100
200
300
400
500
ILOAD (mA)
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MAX13256
36V H-Bridge Transformer
Driver for Isolated Supplies
Typical Operating Characteristics (continued)
(VDD = 24V, TA = +25NC, unless otherwise noted.)
ISOLATED OUTPUT VOLTAGE
vs. LOAD CURRENT
16
14
4
12
10
8
3
6
2
4
1
2
800
1200
1600
100
200
VDD = 24V
80
60
VDD = 8V
40
VDD = 12V
30
250
500
750
VDD = 36V
70
VDD = 32V
60
50
40
10
1250
VDD = 36V
90
80
70
VDD = 28V
60
VDD = 8V
900
VDD = 32V
50
40
4:1 TRANSFORMER
FULL-WAVE RECTIFIER
WITH SNUBBER
0
1500
0
50
0
100 150 200 250 300 350 400
250
500
750
1000
1250
1500
ILOAD (mA)
ILOAD (mA)
1000
VDD = 24V
100
10
MAXIMUM OUTPUT CURRENT
vs. TEMPERATURE
MAXIMUM OUTPUT CURRENT
vs. TEMPERATURE
800
ILOAD (mA)
20
0
1000
ILOAD (mA)
VDD = 16V
100 150 200 250 300 350 400
30
1:1 TRANSFORMER
FULL-WAVE RECTIFIER
WITH SNUBBER
20
900
VDD = 36V
700
VDD = 16V
VDD = 8V
VDD = 24V
VDD = 36V
800
IST1, ST2 (mA)
0
IST1, ST2 (mA)
0
50
EFFICIENCY vs. LOAD CURRENT
30
4:1 TRANSFORMER
FULL-WAVE RECTIFIER
NO SNUBBER
10
0
500
80
MAX13256 toc15
20
400
VDD = 28V
90
EFFICIENCY (%)
70
50
300
EFFICIENCY vs. LOAD CURRENT
100
MAX13256 toc12
VDD = 16V
1:1 TRANSFORMER
FULL-WAVE RECTIFIER
NO SNUBBER
ILOAD (mA)
EFFICIENCY vs. LOAD CURRENT
90
40
0
0
2000
ILOAD (mA)
100
VDD = 24V
VDD = 16V
50
10
EFFICIENCY (%)
400
VDD = 8V
60
20
MAX13256 toc13
0
VDD = 12V
70
30
0
0
EFFICIENCY (%)
80
MAX13256 toc14
5
90
MAX13256 toc16
6
VOUT (V)
VOUT (V)
7
VDD = 24V
4:1 TRANSFORMER
VOLTAGE DOUBLER
NO SNUBBER
18
EFFICIENCY (%)
8
MAX13256 toc10
VDD = 24V
4:1 TRANSFORMER
FULL-WAVE RECTIFIER
NO SNUBBER
9
EFFICIENCY vs. LOAD CURRENT
100
20
MAX13256 toc09
10
MAX13256 toc11
ISOLATED OUTPUT VOLTAGE
vs. LOAD CURRENT
700
600
500
600
400
500
SINGLE-LAYER BOARD
MULTILAYER BOARD
300
400
-40 -25 -10 5 20 35 50 65 80 95 110 125
-40 -25 -10 5 20 35 50 65 80 95 110 125
TA (°C)
TA (°C)
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MAX13256
36V H-Bridge Transformer
Driver for Isolated Supplies
Pin Configuration
TOP VIEW
ST1
10
GND ST2
9
8
GND FAULT
6
7
MAX13256
*EP
+
1
2
3
4
5
VDD
VDD
CLK
EN
ITH
TDFN
*EXPOSED PAD—CONNECT TO GND
Pin Description
PIN
NAME
FUNCTION
1, 2
VDD
Power Supply. Bypass VDD to ground with a 1FF capacitor as close as possible to the device.
3
CLK
Clock Input. Connect CLK to GND to enable internal clocking. Apply a clock signal to CLK to enable external clocking.
4
EN
Enable Input. Drive EN low to enable the device. Drive EN high to disable the device.
5
ITH
Overcurrent Threshold Adjustment Input. Connect a resistor (RLIM) from ITH to GND to set the overcurrent
threshold for the ST1 and ST2 outputs. Do not exceed 10pF of capacitance to GND on ITH.
6
FAULT
7, 9
GND
Ground
Fault Open-Drain Output. The fault open-drain transistor turns on when there is either an overtemperature or
overcurrent condition.
8
ST2
Transformer Drive Output 2
10
ST1
Transformer Drive Output 1
—
EP
Exposed Pad. Internally connected to GND. Connect EP to a large ground plane to maximize thermal performance; not intended as an electrical connection point.
����������������������������������������������������������������� Maxim Integrated Products 7
MAX13256
36V H-Bridge Transformer
Driver for Isolated Supplies
Functional Diagram
VDD
VDD
MAX13256
UVLO
P
ST1
VUVLO
OSC
N
CLK
MUX
FLIPFLOP
MOSFET
H-BRIDGE
DRIVER
VDD
P
WATCHDOG
ST2
EN
ITH
CURRENT
LIMIT
N
FAULT
GND
Detailed Description
The MAX13256 is an integrated primary-side controller
and H-bridge driver for isolated power-supply circuits.
The device contains an on-board oscillator, protection circuitry, and internal MOSFETs to provide up to
300mA of current to the primary winding of a transformer. The device can be operated using the internal
oscillator or driven by an external clock to synchronize
multiple MAX13256 devices and control EMI behavior.
Regardless of the clock source being used, an internal
flip-flop stage guarantees a fixed 50% duty cycle to
prevent DC current flow in the transformer as long as the
period of the clock is constant.
The device operates from a wide single-supply voltage
of 8V to 36V, and includes undervoltage lockout for controlled startup. The device features break-before-make
switching to prevent cross conduction of the H-bridge
MOSFETs. An external resistor sets an overcurrent limit,
allowing primary-side limiting of load currents on the
transformer’s secondary side. Thermal-shutdown circuitry provides additional protection against excessive
power dissipation.
Isolated Power Supply
The MAX13256 allows a versatile range of secondaryside rectification circuits (see Figure 3). The primary-tosecondary transformer winding ratio can be chosen to
adjust the isolated output voltage. The device delivers
up to 300mA of current to the transformer with a supply
up to +36V.
The MAX13256 provides the advantages of the H-bridge
converter topology, including multiple isolated outputs,
step-up/step-down or inverted output, relaxed filtering
requirements, and low output ripple.
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MAX13256
36V H-Bridge Transformer
Driver for Isolated Supplies
Clock Source
Either the internal oscillator or an external clock provides
the switching signal for the MAX13256. Connect CLK to
ground to select the internal oscillator. Provide a clock
signal to CLK to automatically select external clocking.
Internal Oscillator Mode
The MAX13256 includes an internal oscillator that drives
the H-bridge when a watchdog timeout is detected on
CLK. The outputs switch at 425kHz (typ) with a guaranteed 50% duty cycle in the internal oscillator mode.
External Clock Mode
The MAX13256 provides an external clock mode. When
an external clock source is applied to CLK, the external
clock drives the H-bridge. An internal flip-flop divides the
external clock by two in order to generate a switching
signal with a guaranteed 50% duty cycle. As a result, the
device outputs switch at one-half of the external clock
frequency. The device switches on the rising edge of the
external clock signal.
Watchdog
A stalled clock could cause excessive DC current to
flow through the primary winding of the transformer. The
MAX13256 features an internal watchdog circuit to prevent damage from this condition. The internal oscillator
provides the switching signal to the H-bridge whenever
the period between edges on CLK exceeds the watchdog timeout period of 20Fs (min).
Power-Up and Undervoltage Lockout
The MAX13256 provides an undervoltage-lockout feature
to both ensure a controlled power-up state and prevent
operation before the oscillator has stabilized. On powerup and during normal operation if the supply voltage
drops below VUVLO, the undervoltage-lockout circuit
forces the device into disable mode. The ST1 and ST2
outputs are high impedance in disable mode.
Overcurrent Limiting
The MAX13256 limits the ST1/ST2 output current. Connect
an external resistor (RLIM) to ITH to set the current limit.
When the current reaches the limit for longer than the
blanking time of 1.2ms (typ), the drivers are disabled and
FAULT is asserted low. The drivers are reenabled after
the autoretry time of 38.4ms (typ). If a continuous fault
condition is present, the duty cycle of the fault current is
approximately 3%.
To set the current-limit threshold, use the following equation:
RLIM (I) = 650mV/IST1, ST2 (mA)
where IST1, ST2 is the desired current threshold in the
range of 215mA < IST1, ST2 < 650mA (typ). For example,
a 1kI resistor sets the current limit to 650mA. Use a 1%
resistor for RLIM for increased accuracy.
Transients on ST1/ST2 During tDEAD
Ensure that the overcurrent threshold is set to at least
twice the expected maximum operating current. For an
expected maximum operating current of 300mA, set the
ILIM to 650mA. For an expected operating current of
100mA, set the ILIM to 215mA.
Disable Mode
The FAULT output is asserted low whenever the device
is disabled due to a fault condition. FAULT is automatically deasserted when the device is enabled after the
autoretry time following an overcurrent fault, resulting in
FAULT toggling during a continuous overcurrent condition. FAULT is asserted for the entire duration of an overtemperature fault. FAULT is an open-drain output.
When the MAX13256 switches, there is a period of time
when both ST1 and ST2 are high impedance to ensure
that there are no shoot-through currents in the H-bridge.
During this dead time, the voltage at these pins may
temporarily exceed the absolute maximum ratings due
to the inductive load presented by the transformer. This
transient voltage will not damage the device.
The MAX13256 provides a disable mode to reduce current consumption. The ST1 and ST2 outputs are high
impedance in disable mode.
FAULT Output
Thermal Shutdown
The MAX13256 is protected from overtemperature damage by a thermal-shutdown circuit. When the junction
temperature (TJ) exceeds +160NC, the device is disabled
and FAULT is asserted low. FAULT stays low for the duration of an overtemperature fault. The device resumes
normal operation when TJ falls below +150NC.
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MAX13256
36V H-Bridge Transformer
Driver for Isolated Supplies
Applications Information
N:1 CT
+
VOUT = 1/(2 x N) x VIN - VD
+
VIN
-
-
VD = DIODE FORWARD VOLTAGE
FIGURE 3A. PUSH-PULL RECTIFICATION
Snubber
For VDD greater than 27V, use a simple RC snubber
circuit on ST1 and ST2 to ensure that the peak voltage is
less than 40V during switching (Figure 4). Recommended
values for the snubber are R = 91I and C = 330pF.
Power Dissipation
The power dissipation of the device is approximated by:
PD = (ROHL x IPRI2) + (IDD x VDD)
N:1
+
+
VOUT = 2(VIN/N - VD)
VIN
-
-
High-Temperature Operation
FIGURE 3B. VOLTAGE DOUBLER
N:1
+
VIN
+
VOUT = VIN/N - 2VD
-
where ROHL is the combined high-side and low-side onresistance of the internal FET drivers, and IPRI is the load
current flowing through ST1 and ST2.
-
FIGURE 3C. FULL-WAVE RECTIFIER
When the MAX13256 is operated under high ambient
temperatures, the power dissipated in the package can
raise the junction temperature close to thermal shutdown.
Under such temperature conditions, the power dissipation should be held low enough so that that junction temperature observes a factor of safety margin. The maximum
junction temperature should be held below +140°C. Use
the package’s thermal resistances to calculate the junction temperature. Alternatively use the Maximum Output
Current vs. Temperature curves shown in the Typical
Operating Characteristics section to determine the maximum ST1/ST2 load currents.
Figure 3. Secondary-Side Rectification Topologies
Hot Insertion
If the MAX13256 is inserted into a live backplane, it is
possible to damage the device. Damage is caused by
overshoot on VDD exceeding the absolute maximum
rating. Limit the transient input voltage to the MAX13256
with an external protection device.
ST1
Output-Ripple Filtering
ST2
R
91I
R
91I
C
330pF
C
330pF
Output-voltage ripple can be reduced with a lowpass LC
filter (see Figure 5). The component values shown give a
cutoff frequency of 21.5kHz by the equation:
f3dB =
Figure 4. Output Snubber
L
25µH
FILTER
OUTPUT
C
2.2µF
1
2π LC
Use an inductor with low DC resistance and sufficient saturation current rating to minimize filter power dissipation.
Power-Supply Decoupling
Bypass VDD to ground with a 1FF ceramic capacitor as
close as possible to the device.
Figure 5. Output Ripple Filtering
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MAX13256
36V H-Bridge Transformer
Driver for Isolated Supplies
Output-Voltage Regulation
For many applications, the unregulated output of the
MAX13256 meets the output-voltage tolerances. This
configuration represents the highest efficiency possible
with the device.
For applications requiring a regulated output voltage, Maxim
provides several solutions. In the following examples, assume
a tolerance of Q10% for the input voltage.
When the load currents on the transformer’s secondary
side are low, the output voltage can strongly increase.
If operation under low load currents is expected, outputvoltage limiting should be used to keep the voltage within
the tolerance range of the subsequent circuitry. If the minimum output load current is less than approximately 5mA,
connect a zener diode from the output node to ground as
shown in Figure 6 to limit the output voltage to a safe value.
Example 1: +24V to Isolated, Regulated +3.3V
In Figure 6, the MAX13256 feeds approximately +4.4V to the
input of an LDO through a TGMR-502V6LF 4:1 transformer
and 4-diode bridge rectifier (see Figure 3C). From this, a
MAX604 LDO produces a regulated +3.3V output at up
to 500mA.
Example 2: +24V to Isolated, Regulated +12V
In the circuit of Figure 7, the MAX13256 feeds approximately +14.2V through a 1.5:1 transformer and a 4-diode
bridge rectifier (see Figure 3C). From this, a MAX1659
LDO produces a regulated +12V output at up to 350mA.
+24V
1µF
VDD
TGMR-502V6LF
MBRS140 x 4
ST1
EN
MAX13256
MAX604
+
10µF +3.3V
-
MAX1659
+
10µF +12V
-
10µF
CLK
ST2
4:1
GND
Figure 6. +24V to Isolated, Regulated +3.3V
+24V
1µF
VDD
MBRS140 x 4
ST1
EN
MAX13256
1.0µF
CLK
ST2
1.5:1
GND
Figure 7. +24V to Isolated, Regulated +12V
���������������������������������������������������������������� Maxim Integrated Products 11
MAX13256
36V H-Bridge Transformer
Driver for Isolated Supplies
Example 3: +24V to Isolated, Regulated ±15V
In Figure 8, the MAX13256 is used with a 1:1.5 center
tapped transformer and a 4-diode bridge rectifier network (see Figure 3C) to supply Q17.1V to a MAX8719
LDO and a 7915 LDO. The circuit produces regulated
Q15V outputs at up to 100mA.
Isolated DAC/ADC Interface for
Industrial Process Control
The MAX13256 provides isolated power for data converters in industrial process control applications (see
Figure 9). The 300mA output current capability allows
for multiple data converters operating across an isolation barrier. The power output capability also supports
circuitry for signal conditioning and multiplexing.
+24V
1µF
ST1
EN
1:1.5 CT
4 x MBRS140
MAX13256
+15V
MAX8719
ST2
CLK
GND
R1
0.1µF
10µF
R2
COMMON
0.1µF
10µF
7915
-15V
Figure 8. +24V to Isolated, Regulated ±15V
���������������������������������������������������������������� Maxim Integrated Products 12
MAX13256
36V H-Bridge Transformer
Driver for Isolated Supplies
VDD
MAX13256
+15V
COMMON
-15V
VDD
RS485
MPU
OPTOISOLATORS
M
U
X
DAC/ADC
OPTOISOLATORS
Figure 9. Isolated Power Supply for Industrial Control Applications
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MAX13256
36V H-Bridge Transformer
Driver for Isolated Supplies
Isolated RS-485/RS-232 Data Interfaces
The MAX13256 provides power for multiple transceivers
in isolated RS-485/RS-232 data interface applications.
The 300mA output current capability of the MAX13256
allows multiple RS-485/RS-232 transceivers to operate
simultaneously.
PCB Layout Guidelines
As with all power-supply circuits, careful PCB layout is important to achieve low switching losses and
stable operation. For thermal performance, connect the
exposed pad to a solid copper ground plane.
The traces from ST1 and ST2 to the transformer must be
low resistance and inductance paths. Place the transformer as close as possible to the MAX13256 using short,
wide traces.
When the device is operating with the internal oscillator,
it is possible for high-frequency switching components
on ST1 and ST2 to couple into the CLK circuitry through
PCB parasitic capacitance. This capacitive coupling can
induce duty-cycle errors in the oscillator, resulting in a DC
current through the transformer. To ensure proper operation, ensure that CLK has a solid ground connection.
Exposed Pad
Ensure that the exposed pad has a solid connection to
the ground plane for best thermal performance. Failure
to provide a low thermal impedance path to the ground
plane results in excessive junction temperatures when
delivering maximum output power.
Component Selection
Transformer Selection
Transformer selection for the MAX13256 can be simplified by the use of a design metric, the ET product. The
ET product relates the maximum allowable magnetic flux
density in a transformer core to the voltage across a winding and switching period. Inductor magnetizing current in
the primary winding changes linearly with time during the
switching period of the device. Transformer manufacturers specify a minimum ET product for each transformer.
The transformer’s ET product must be larger than:
ET = VDD/(2 x fSW)
where fSW is the minimum switching frequency of the
ST1/ST2 outputs (255kHz (min)) when the internal oscillator is used or one-half of the clock frequency when an
external clock source is used.
Choose a transformer with sufficient ET product in the
primary winding to ensure that the transformer does not
saturate during operation. Saturation of the magnetic
core results in significantly reduced inductance of the
primary, and therefore a large increase in current flow.
This can cause the current limit to be reached even when
the load is not high.
For example, when the internal oscillator is used to drive
the H-bridge, the required transformer ET product for an
application with VDD(max) = 36V is 70.6VFs. An application with VDD(max) = 8.8V has a transformer ET product
requirement of 17.3VFs.
In addition to the constraint on ET product, choose a
transformer with a low DC-winding resistance. Power
dissipation of the transformer due to the copper loss is
approximated as:
PD_TX = ILOAD2 x (RPRI/N2 + RSEC)
where RPRI is the DC winding resistance of the primary,
and RSEC is the DC winding resistance of the secondary. In most cases, an optimum is reached when RSEC =
RPRI/N2. For this condition, the power dissipation is equal
for the primary and secondary windings.
As with all power-supply designs, it is important to optimize efficiency. In designs incorporating small transformers, the possibility of thermal runaway makes low
transformer efficiencies problematic. Transformer losses
produce a temperature rise that reduces the efficiency of
the transformer. The lower efficiency, in turn, produces
an even larger temperature rise.
To ensure that the transformer meets these requirements under all operating conditions, the design should
focus on the worst-case conditions. The most stringent
demands on ET product arise for minimum input voltage, switching frequency, and maximum temperature
and load current. Additionally, the worst-case values for
transformer and rectifier losses should be considered.
The primary should be a single winding; however, the
secondary can be center-tapped, depending on the
desired rectifier topology. In most applications, the phasing between primary and secondary windings is not significant. Half-wave rectification architectures are possible
with the MAX13256; however, these are discouraged.
If a net DC current results due to an imbalanced load,
the average magnetic flux in the core is increased. This
reduces the effective ET product and can lead to saturation of the transformer core.
���������������������������������������������������������������� Maxim Integrated Products 14
MAX13256
36V H-Bridge Transformer
Driver for Isolated Supplies
Transformers for use with the device are typically wound
on a high-permeability magnetic core. To minimize radiated electromagnetic emissions, select a toroid, pot core,
E/I/U core, or equivalent.
that the average forward current rating for the rectifier
diodes exceeds the maximum load current of the circuit.
For surface-mount applications, Schottky diodes such as
the BAT54, MBRS140, and MBRS340 are recommended.
Low-Voltage Operation
Capacitor Selection
The MAX13256 can be operated from an +8V supply by
decreasing the turns ratio of the transformer, or by designing a voltage doubler circuit as shown in Figure 3B.
Optimum performance at +8V is obtained with fewer
turns on the primary winding since the ET product
requirement is lower than for a +24V supply. However,
any of the transformers for use with a +24V supply can
operate properly with a +8V supply. For a given power
level, the transformer currents are higher with a +8V
supply than with a +24V supply. Therefore, the DC resistance of the transformer windings has a larger impact on
the circuit efficiency.
Diode Selection
The high switching speed of the MAX13256 necessitates
high-speed rectifiers. Ordinary silicon signal diodes
such as 1N914 or 1N4148 can be used for low-output
current levels (less than 50mA.) But at higher output current levels, their reverse recovery times might degrade
efficiency. At higher output currents, select low forwardvoltage Schottky diodes to improve efficiency. Ensure
Input Bypass Capacitor
Bypass the supply pin to GND with a 1FF ceramic
capacitor as close as possible to the device. The equivalent series resistance (ESR) of the input capacitors is not
as critical as for the output filter capacitors. Typically
ceramic X7R capacitors are adequate.
Output Filter Capacitor
In most applications, the actual capacitance rating of the
output filter capacitors is less critical than the capacitor’s
ESR. In applications sensitive to output-voltage ripple,
the output filter capacitor must have low ESR. For optimal
performance, the capacitance should meet or exceed
the specified value over the entire operating temperature
range. Capacitor ESR typically rises at low temperatures;
however, OS-CON capacitors can be used at temperatures below 0NC to help reduce output-voltage ripple in
sensitive applications. In applications where low outputvoltage ripple is not critical, standard ceramic 0.1FF
capacitors are sufficient.
Suggested External Component Manufacturers
Table 1. Component Manufacturers
MANUFACTURER
Central Semiconductor
Halo Electronics
COMPONENT
Diodes
Transformers
WEBSITE
www.centralsemi.com
www.haloelectronics.com
Kemet
Capacitors
www.kemet.com
Sanyo
Capacitors
www.sanyo.com
Taiyo Yuden
Capacitors
www.t-yuden.com
TDK
Capacitors
www.component.tdk.com
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MAX13256
36V H-Bridge Transformer
Driver for Isolated Supplies
Ordering Information
PART
TEMP RANGE
MAX13256ATB+
-40NC to +125NC
PIN-PACKAGE
10 TDFN-EP*
+Denotes a lead(Pb)-free/RoHS-compliant package.
*EP = Exposed Pad
Chip Information
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.
10 TDFN-EP
T1033+1
21-0137
90-0003
PROCESS: BiCMOS
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MAX13256
36V H-Bridge Transformer
Driver for Isolated Supplies
Revision History
REVISION
NUMBER
REVISION
DATE
0
6/11
DESCRIPTION
Initial release
PAGES
CHANGED
—
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. The parametric values (min and max limits) shown in the Electrical
Characteristics table are guaranteed. Other parametric values quoted in this data sheet are provided for guidance.
Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600
© 2011
Maxim Integrated Products 17
Maxim is a registered trademark of Maxim Integrated Products, Inc.