MAXIM MAX845ESA

19-0372; Rev 4; 10/97
KIT
ATION
EVALU
E
L
B
A
AVAIL
Isolated Transformer Driver
for PCMCIA Applications
____________________________Features
♦ Transformer Driver for Ultra-Thin 5V-µs Transformers
The MAX845 consists of an oscillator followed by a toggle flip-flop. The flip-flop generates two 50% duty-cycle
square waves, which are complementary at half the
oscillator frequency (450kHz, min). These two signals
drive the ground-referenced N-channel power switches. Internal circuitry ensures break-before-make action
between the two switches.
A low-power shutdown disables both the switches and
the oscillator, reducing power consumption. An evaluation kit (MAX845EVKIT-MM) is available to evaluate lowprofile 5V 40mA and 5V 100mA applications.
________________________Applications
♦ Isolated DC-to-DC Power Supply for PCMCIA
Applications
♦ 450kHz Minimum Switching Frequency
♦ Ultra-Low Input Supply Current Ripple
♦ Single +5V or +3.3V Supply
♦ 5µW Low-Power Shutdown Mode
♦ 8-Pin SO and µMAX Packages
♦ Low Output Ripple Permits Miniature Output
Capacitors
_______________Ordering Information
PCMCIA Modem Cards
PART
Isolated Data Acquisition
Isolated Interface Power Supply
Noise-Immunity Communications Interface
Bridging Ground Differences
TEMP. RANGE
PIN-PACKAGE
MAX845C/D
0°C to +70°C
Dice*
MAX845ESA
-40°C to +85°C
8 SO
MAX845EUA
-40°C to +85°C
8 µMAX
*Contact factory for dice specifications.
Medical Equipment
Process Control
Low-Power LAN Networks
__________Typical Operating Circuit
VIN
ON / OFF
4
6
SD
VCC
D1
5V
TOP VIEW
C1
CR1
1
OUTPUT
5V @ 150mA
C2
MAX845
3
FREQUENCY
SELECT
FS
D2
GND1
GND2
2
7
___________________Pin Configuration
D1
1
GND1
2
FS 3
8
MAX845
SD 4
T1
C3
8
D2
7
GND2
6
VCC
5
N.C.
SO/µMAX
CR2
________________________________________________________________ Maxim Integrated Products
1
For free samples & the latest literature: http://www.maxim-ic.com, or phone 1-800-998-8800.
For small orders, phone 408-737-7600 ext. 3468.
MAX845
_______________General Description
The MAX845 provides an isolated power supply small
enough to fit in thin PCMCIA cards and space-sensitive
applications. It drives a low-profile center-tapped transformer primary from a 5V or 3.3V DC power supply. The
secondary can be wound to provide any isolated positive or negative voltage at powers up to 750mW.
MAX845
Isolated Transformer Driver
for PCMCIA Applications
ABSOLUTE MAXIMUM RATINGS
Supply Voltage (VCC) ...............................................-0.3V to +7V
Control Input Voltage (SD, FS) ...................-0.3V to (VCC + 0.3V)
Peak Output Switch Current (D1, D2) ......................................1A
Output Switch Voltage (D1, D2) .............................................12V
Average Output Switch Current (D1, D2) .........................200mA
Continuous Power Dissipation (TA = +70°C)
SO (derate 5.88mW/°C above +70°C) .........................471mW
µMAX (derate 4.10mW/°C above +70°C) ....................330mW
Operating Temperature Range ...........................-40°C to +85°C
Storage Temperature Range .............................-65°C to +160°C
Junction Temperature ......................................................+150°C
Lead Temperature (soldering, 10sec) .............................+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
(VCC = 5V ±10%, TA = TMIN to TMAX, unless otherwise noted. Typical values are at TA = +25°C.)
PARAMETER
Switch On-Resistance
Switch Frequency
CONDITIONS
MIN
TYP
FS = VCC = 4.5V
450
FS = VCC = 5.5V
550
860
1100
D1, D2; 100mA
MAX
UNITS
1.5
4.0
Ω
675
900
FS = 0V, VCC = 4.5V
500
FS = 0V, VCC = 5.5V
575
Operating Supply Current (Note 1)
No load, SD = 0V, FS = VCC
1.1
Shutdown Supply Current (Note 2)
SD = VCC
Shutdown Input Threshold
High
0.4
Low
0.8
FS Input Current
Minimum Start-Up Voltage
10
High
Low
0.8
FS = 0V
50
10
2.5
2.2
Note 1: Operating supply current is the current used by the MAX845 only. Load current is not included.
Note 2: Shutdown supply current includes output switch leakage currents.
2
_______________________________________________________________________________________
V
pA
2.4
FS = VCC
mA
µA
2.4
Shutdown Input Leakage Current
FS Input Threshold
5.0
kHz
V
µA
V
Isolated Transformer Driver
for PCMCIA Applications
30
25
VIN = 5.5V
15
6.5
6.0
5.5
5.0
4.5
4.0
3.5
40
60
80
-40
100
-20
0
TEMPERATURE (°C)
D1, D2 FREQUENCY vs. TEMPERATURE
VIN = 5.0V
750
700
650
600
550
600
-40
500
-40
40
60
80
100
60
FIGURE 11c
50
40
30
-20
20
0
40
60
80
80
100 120 140 160
LOAD CURRENT (mA)
VIN = 4.5V
-40
0
-20
20
40
60
80
100
15
TRANSFORMERS
USED IN FIGURE 11c
14
13
TGM-030P3
TGM-010P3
4.5
4.0
TGM-020P3
12
TGM-030P3
11
10
TGM-010P3
9
8
7
TGM-020P3
6
2.5
60
1.0
OUTPUT VOLTAGE vs. LOAD CURRENT
5.0
3.0
40
VIN = 5.0V
1.1
TEMPERATURE (°C)
5.5
3.5
0
TRANSFORMERS
USED IN FIGURE 11b
6.0
10
20
1.2
100
6.5
20
0
VIN = 5.5V
1.3
0.8
7.0
OUTPUT VOLTAGE (V)
EFFICIENCY (%)
FIGURE 11b
100
1.4
OUTPUT VOLTAGE vs. LOAD CURRENT
70
80
VIN = 6.0V
0.9
7.5
MAX845-07
90
60
40
1.5
TEMPERATURE (°C)
EFFICIENCY vs. LOAD CURRENT
100
20
1.6
FS LOW
TEMPERATURE (°C)
80
0
1.7
OUTPUT VOLTAGE (V)
20
-20
SUPPLY CURRENT vs. TEMPERATURE
FS HIGH
750
650
0
-40
TEMPERATURE (°C)
VIN = 5.0V
VIN = 4.5V
-20
100
800
FREQUENCY (kHz)
FREQUENCY (kHz)
VIN = 5.5V
700
80
D1, D2 FREQUENCY vs. TEMPERATURE
VIN = 6.0V
800
60
850
MAX845-04
950
850
0.6
TEMPERATURE (°C)
1000
900
40
20
SUPPLY CURRENT (mA)
20
MAX845-05
0
MAX845-08
-20
0.8
0.2
2.5
-40
1.0
0.4
3.0
10
1.2
MAX845-06
20
SD = VCC
1.4
MAX845-09
OUTPUT RESISTANCE (Ω)
VIN = 4.5V
SHUTDOWN CURRENT (µA)
35
FIGURE 11b
7.0
1.6
MAX845-02
FIGURE 11c
OUTPUT RESISTANCE (Ω)
7.5
MAX845-01
40
SHUTDOWN SUPPLY CURRENT
vs. TEMPERATURE
OUTPUT RESISTANCE vs. TEMPERATURE
MAX845-03
OUTPUT RESISTANCE vs. TEMPERATURE
5
0
20
40
60
80
100 120 140 160
LOAD CURRENT (mA)
0
20
40
60
80
100 120 140 160
LOAD CURRENT (mA)
_______________________________________________________________________________________
3
MAX845
__________________________________________Typical Operating Characteristics
(Typical Operating Circuit, VIN = 5V, C1 = 0.1µF, C2 = C3 = 0.33µF, T1 = Halo TGM-010P3, CR1 = CR2 = MBR0520, FS = VCC,
TA = +25°C, unless otherwise noted.)
MAX845
Isolated Transformer Driver
for PCMCIA Applications
____________________________Typical Operating Characteristics (continued)
(Typical Operating Circuit, VIN = 5V, C1 = 0.1µF, C2 = C3 = 0.33µF, T1 = Halo TGM-010P3, CR1 = CR2 = MBR0520, FS = VCC,
TA = +25°C, unless otherwise noted.)
SWITCHING WAVEFORM
(BREAK-BEFORE-MAKE)
SWITCHING WAVEFORMS
(TWO CYCLES)
D1OFF
D1
D2OFF
500mV/div
5V/div
D2
CIRCUIT
OF FIG. 1
D2ON
400ns/div
D1ON
200ns/div
TIME FROM SHUTDOWN TO POWER-UP
SD
2V/div
OUTPUT
5µs/div
_____________________Pin Description
VIN
4
PIN
NAME
FUNCTION
1
D1
Open Drain of N-Channel Transformer Drive 1
2
GND1
Ground. Connect both GND1 and GND2 to
ground.
3
FS
Frequency Select (internal pull-up). If FS =
VCC or open, switch frequency = 725kHz; if
FS = 0V, switch frequency = 535kHz.
4
SD
Shutdown. Ground for normal operation,
connect to VCC for shutdown.
5
N.C.
No Connect. Not internally connected.
6
VCC
+5V Supply Voltage
7
GND2
Ground. Connect both GND1 and GND2 to
ground.
8
D2
Open Drain of N-Channel Transformer Drive 2
5V
C1
0.1µF
R1
50Ω
6
VCC
4
SD
D1
1
ON / OFF
R2
50Ω
MAX845
3
FREQUENCY
SELECT
FS
D2
GND1
2
GND2
7
Figure 1. Test Circuit
_______________________________________________________________________________________
8
Isolated Transformer Driver
for PCMCIA Applications
5V
C1
VCC
D1
Q
OUTPUT
5V @ 150mA
CR1
N
C2
T
FS
FREQUENCY
SELECT
VCC
F/F
MAX845
MAX845
VIN
OSC
400kHz/
700kHz
D2
Q
N
SD
ON / OFF
GND2
CR2
C3
GND1
ISO
GND
Figure 2. Detailed Block Diagram
_______________Detailed Description
The MAX845 is a transformer driver specifically
designed to provide isolated power for PCMCIA and
other height- and/or space-sensitive applications. It
drives a center-tapped transformer primary from a 5V
or 3.3V DC power supply. The secondary can be
wound to provide any isolated DC voltage needed at
power levels up to 750mW.
The 450kHz minimum switching frequency allows the
use of very thin transformers, making the MAX845 ideal
for PCMCIA and other space-limited applications. The
MAX845 is designed to drive a single transformer less
than 0.09 inches (2.3mm) in height, including package.
Further reduction down to 0.050 inches (1.27mm) can
be achieved using a transformer without a package.
The MAX845 consists of an RC oscillator driving a pair
of N-channel power switches. The oscillator runs at
double the output frequency, driving a toggle flip-flop
to ensure 50% duty cycle to each of the switches.
Internal circuitry ensures break-before-make action
between the two switches.
A low-current shutdown mode disables all internal circuitry, including the oscillator and both power switches.
Drive the shutdown pin (SD) high to shut down the part;
drive SD low for normal operation. The SD pin has no
internal default condition and must not be allowed to
float.
Most MAX845 applications will operate at high frequencies. The frequency-select pin (FS) is pulled high or left
open (FS is internally pulled up to VCC) to operate at a
minimum of 450kHz. Pulling FS low selects the low-frequency state.
Theory of Operation
Figure 2 shows the MAX845 driving both a TGM-010P3
transformer with a center-tapped primary, and a secondary with a voltage-doubler rectifier topology. All of the
transformers driven by the MAX845 must have a center
tap with VIN applied. Whenever one of the MAX845 outputs (D1 or D2) goes low, the other goes to approximately double the supply voltage. A voltage is induced in the
secondary and the rectifier diodes steer the currents into
the appropriate output capacitor. On alternate half
cycles, each capacitor is charged. The output voltage is
the sum of the voltages from each output capacitor. This
topology yields the simplest and smallest transformer
because the least number of secondary turns is required
for a given voltage.
__________Applications Information
With the MAX845 transformer driver, designers have
the advantages of push/pull converter topology in
space-sensitive applications. The push/pull DC-DC
converter topology allows isolated multiple outputs,
step-up/step-down or inverted outputs, easier filtering
on the input and the output, and lower overall noise.
Isolated Power for PCMCIA Applications
Medical instrumentation, modems, and LAN-interface
cards often require isolated power supplies. One of the
best switching-regulator topologies for this application
is the push/pull forward-converting DC-DC power supply shown in Figures 3 and 4. Because the transformer
works in the forward mode (rather than the flyback
mode), its core does not store energy and, therefore,
can be small. Input and output capacitors can be small
because of the high-frequency and continuous-current
waveforms.
_______________________________________________________________________________________
5
MAX845
Isolated Transformer Driver
for PCMCIA Applications
VIN
5V
0.01µF
1N4148
C1
0.1µF
1N4148
6
4
ON / OFF
3.3V
SUPPLY
VCC
SD
D1
1
MBR0520
1CT:1.3CT
5V @ 150mA
ISO OUTPUT
6
VCC
C2
0.33µF
D1
1
MAX845
MAX845
3
FREQUENCY
SELECT
FS
D2
GND1 GND2
2
8
MBR0520
ISO
GND
7
GND1
2
D2
GND2
8
SEE FIGURE 11
FOR RECTIFIER
CONFIGURATIONS
7
Figure 3. 5V to Isolated 5V Application Circuit
Figure 4. 3.3V Input to Isolated Output Application Circuit
The MAX845 is a versatile transformer driver, capable
of driving a center-tapped transformer primary from a
5V or 3.3V DC power supply (Figures 3 and 4). The
secondary can be wound to provide any isolated voltage needed at power levels up to 750mW with a 5V
supply or up to 500mW with a 3.3V supply. Figure 3
shows a typical 5V to isolated 5V application circuit that
delivers up to 150mA of isolated 5V power.
will be higher at 3.3V, so transformer winding resistance
will be more critical and efficiencies will be lower. The
MAX845 output current must still be limited to 200mA
(see Absolute Maximum Ratings), so the available output power will be less than with a 5V power source.
3.3V Supply
Any of the application circuits shown may be converted
to 3.3V operation by changing the turns ratio of the transformer and operating the MAX845 from a boost supply,
as shown in Figure 4. In normal operation, whenever one
of the MAX845 outputs goes low, the other goes to
approximately double the supply voltage. Since the circuit is symmetrical, the two outputs can be combined
with diodes, lightly filtered, then used to power the
MAX845, and possibly other light loads as well.
The diodes on the primary side may be any fast-switching small-signal diodes, such as the 1N914, 1N4148, or
CMPD2838. The value of the primary filter capacitor is
not critical and can be very small, since it only needs to
supply current to the MAX845 during the break-beforemake interval.
The transformer could be any of the same ones used for
5V operation, but for optimum performance it should
have fewer primary turns, as the ET product required is
now only 3.3V-µs. For a given power level, the currents
6
Low-Noise Power Supply
The MAX845 topology is inherently low noise, in that
either one or the other of the two power devices is on at
any given time. By alternating between two identical
states with one side on and the other off, the input current is nearly constant and secondary output power is
available at all times. There is an intentional breakbefore-make action to prevent any possibility of both
power switches conducting at the same time. During
this 100ns non-overlap interval, the input current goes
to zero. This adds a small high-frequency component
to the input current waveform. This ripple current can
easily be absorbed by a small input bypass capacitor
(0.33µF) from VCC to ground. Figure 5 shows a lownoise bias supply using the MAX845 transformer driver.
When using the two-diode push-pull (Figure 11a)
rectifier or the four-diode bridge (Figure 11b), the output voltage tends to be more constant than in most
alternative topologies. As described above, the circuit
alternates between two identical states that both provide power to the load. The only part of the cycle that
produces output ripple is the 100ns non-overlap interval, which can easily be filtered by a small ceramic
output capacitor (0.33µF).
_______________________________________________________________________________________
Isolated Transformer Driver
for PCMCIA Applications
D1
VCC
MAX845
6
5V
IN
1
0.33µF
MBR0520L*
MAX845
78L05
N.C.
3
IN
FS
OUT
GND
4
0.33µF
D2
SD
GND1
2
GND2
7
N.C.
8
HALO
TGM-030P3
-5V
100mA
5
*1N914 POSSIBLE FOR LOWER CURRENTS
Figure 5. Low-Noise Supply
Isolated Data Conversion
Almost any serial-interface device is a candidate for
operation across an isolation barrier; Figure 6 illustrates
one example. The MAX176 analog-to-digital converter
(ADC) operates from +5V and -12V supplies, provided
by the multiple-tapped secondary and linear regulators.
This circuit easily supplies several hundred milliwatts of
additional isolated power for signal conditioning, multiplexing, or sensors. A +12V supply can be generated
by adding two more diodes from the ends of the secondary, and a -5V supply can be generated by connecting additional diodes to the 1⁄4 and 3⁄4 tap points on
the secondary. The MAX845 supplies sufficient power
for almost any Maxim ADC.
Telephone-Subscriber-Line Power Supply
The standard telephone system is placed in the “off
hook” state by placing a load on the line to signal the
central office that service is requested. Normally, most of
this power is wasted in a load resistor, but some systems
can benefit from utilizing this free power. Figure 7 shows
one way to transform the wasted telephone power to an
isolated, regulated 5V at currents up to 50mA.
Because the telephone line is a high-impedance
source, there can be a start-up problem with any DCto-DC converter; when the line voltage is low during
start-up, the frequency can be too low for the transformer, causing it to saturate. This excess saturation
current can keep the voltage from climbing to normal
operating levels. Thus the purpose of Q1, Q2, and the
associated resistors is to ensure that the MAX845
remains in the shutdown mode until the voltage is high
enough to allow proper operation.
Isolated 4mA to 20mA Analog Interface
The 4mA to 20mA current loop is widely used in the
process-control industry for transducer and actuator
control signals. These signals are commonly referred to
a distant ground that may be at a considerably higher
voltage with respect to the local ground. The circuit in
Figure 8 generates an isolated 4mA to 20mA current
from a 5V supply.
Isolated RS-485 Data Interface
The MAX845 power-supply transformer driver also provides isolated power for RS-485 data-interface applications. The application circuit of Figure 9 combines the
MAX845 with a low-dropout linear regulator, a transformer, several high-speed optocouplers, and a Maxim
RS-485 interface device.
Isolated RS-232 Data Interface
The MAX845 is ideal for isolated RS-232 data-interface
applications requiring more than four transceivers. Its
750mW output power capability enables it to drive 10
transceivers simultaneously. Figure 10 shows the typical application circuit for a complete 120kbps isolated
RS-232 data interface. This figure also shows how the
Sharp PC417 optocouplers can be replaced by the
lower-cost Quality Technologies 4N25 devices to
achieve data transfer rates up to 19.2kbps.
_______________________________________________________________________________________
7
MAX845
Isolated Transformer Driver
for PCMCIA Applications
ISOLATION
BARRIER
1CT : 1.5CT : 3CT
VIN
5V INPUT
1
78L05
4 x 1N5817
10µF
ISO
5V
6
3
8
79L12
ISO
-12V
D1
MAX845
VCC
FS
D2
GND1
10µF
4
SD
2
ON/OFF
GND2
7
74HC04
START
8
6N136
7
INPUT CLOCK
1
2
200Ω
QH
3k
14
6
10µF
5
MAX176
0.1µF
ANALOG
INPUT
1
2
3
0.1µF
10µF
VDD
AIN
VREF
VSS
CONVST
CLOCK
4
GND
3
DATA
8
8
7
6
5
6N136
7
4
11
1
12
200Ω
5V
INPUT
0.1µF 10µF
SIGNAL
GROUND
3
5
1
QC
RCK
10
QA
SCLR
5
4
3
2
1
15
8
D11(MSB)
D10
D9
D8
5V
INPUT
0.1µF
74HC04
8
2
7
3
6
4
5
8
QH′
8.2k
14
11
QH
QG
SER
74HC595 QF
QE
SCK
QD
12
QC
RCK
QB
5V
INPUT
10
QA
SCLR
7
6
5
4
3
2
1
15
16
13
Figure 6. Typical Isolated Data-Conversion Application
8
6
16
13
4
6N136
QE
SCK
QB
3k
470Ω
74HC595 QF
QD
2
6
QG
SER
7
_______________________________________________________________________________________
8
D7
D6
D5
D4
D3
D2
D1
D0 (LSB)
5V
INPUT
0.1µF
Isolated Transformer Driver
for PCMCIA Applications
MAX845
TELEPHONE SUBSCRIBER LINE
ISOLATION
BARRIER
6.8V
2W
1k
D1
6
VCC
Q1
2N3906
100k
D1
1
T1
1:2:1
D2
1N5817
22k
IC2
TL431
0.1µF
C1
0.1µF
IC1
22k
100k
4
2M
680k
MAX845
SD
D2
FS
100k
Q2
2N3904
100k
5V @ 50mA
ISO OUTPUT
GND1
2
ISO
GND
8
3
N.C.
D3
1N5817
GND2
7
Figure 7. 5V from Telephone-Subscriber Line
VIN
ISOLATION
BARRIER
1CT:5CT
6
5V
VCC
D1
1
24V UNREGULATED
1N5817
10µF
IN
78L05
MAX845
4
SD
GND1
2
GND
GND2
7
D2
8
OUT
1N5817
3
3
1
7
0.1V to 0.5V
MAX480
2
6
4
49.9k
IL300
2
2
3
6
4
5
6
MAX480
ISO
5V
7
RL
0k to 1k
IOUT
4mA to 20mA
2N3904
4
2N3904
10k
49.9k
24.9Ω
Figure 8. Typical 4mA/20mA Application Circuit
_______________________________________________________________________________________
9
MAX845
Isolated Transformer Driver
for PCMCIA Applications
ISOLATION
BARRIER
VIN
5V
C1
0.1µF
6
VCC
D1
ON / OFF
4
SD
2
8
C3
0.1µF
MAX845
D2
GND1
ICT:1.3CT 1N5817
1
GND2
FS
IN
OUT
C2
2.2µF
ISO 5V
2
C4
2.2µF
MAX883
8
3
1N5817
N.C.
SET
GND
6
SHDN
4
5
7
3.3k
PC410 / 417
6
*74HC04
390Ω
DI
1
5
3.3k
3
8
4
PC357T
*74HC04
390Ω
DE
4
1
4
A
3
*74HC04
3.3k
DE
1
B
1
RO
RE
GND
2
*74HC04 OR EQUIVALENT
4
3
Figure 9. Typical RS-485 Application Circuit
10
485
I/O
6
390Ω
6
MAX481
MAX483
MAX485
MAX487
2
3
PC410 / 417
5
RO
VCC
DI
______________________________________________________________________________________
5
7
Isolated Transformer Driver
for PCMCIA Applications
5V
C1
0.1µF 5
ON / OFF
4
6
VCC
N.C.
SD
D1
1
MAX845
D2
FS
GND1 GND2
2
7
8
2
IN
OUT
C2
2.2µF
MAX883
C3
0.1µF
SET GND SHDN
6
4
5
MBR0520
N.C.
5 x 3.3k
390Ω
6
1
T1IN
3
5
4
2
74HC04
390Ω
4
T2IN
74HC04
ISO 5V
C4
2.2µF
8
3
10 x PC417
*74HC04
MAX845
ISOLATION
BARRIER
1CT:1.3CT
MBR0520
VIN
390Ω
25
27, 28 13, 14
VCC
GND
11
T1IN
T1OUT
T2IN
T2OUT
T3IN
T3OUT
T4IN
T4OUT
T5IN
T5OUT
12
18
T3IN
74HC04
390Ω
24
T4IN
74HC04
390Ω
23
T5IN
R1OUT
74HC04
6
5
4
1
390Ω
5
390Ω
6
390Ω
7
R3OUT
74HC04
390Ω
22
R4OUT
74HC04
R5OUT
R1OUT
R1IN
R2OUT
R2IN
R3OUT
R3IN
R4OUT
R4IN
R5OUT
R5IN
10
2
R2OUT
74HC04
16
MAX225
5 x 3.3k
74HC04
17
390Ω
21
SD
1
9
8
19
20
EN
2
*74HC04 OR EQUIVALENT
4N25 LOWER SPEED, LOWER COST ALTERNATE OPTOCOUPLER CONFIGURATIONS (FOR DATA RATES BELOW 9.6kbps)
VCC
1N5711
4N25 6 1N5711
6 4N25
3.3k
3.3k
390Ω
1
1
ROUT
TIN
ISO
5
5
TIN
390Ω
74HCO4
*74HC04
2
2 ISO
ISO
4
4 GND
GND
VCC
ISO
ROUT
Figure 10. Typical RS-232 Application Circuit
______________________________________________________________________________________
11
MAX845
Isolated Transformer Driver
for PCMCIA Applications
______________Component Selection
Transformer
The MAX845 drives any transformer that has a centertapped primary and a saturation rating of at least 5V-µs
(ET product) per side. The oscillator frequency varies
linearly with VCC. The transformer is most vulnerable to
saturation at the minimum frequency, because the
switches are on for the longest period. At VCC = 4.5V,
the transformer must withstand at least:
1
1
4.5V x ———–——— x — = 5V-µs
450kHz min
2
And at VCC = 5.5V, the transformer must withstand
at least:
1
1
5.5V x ———–——— x — = 5V-µs
550kHz min
2
Thus, the required ET product is constant over the
entire 5V ±10% range.
Select either a toroid or a gapped core. Although some
applications will require custom transformers, many
can use standard transformer designs, such as those
listed in Table 1. Some of these manufacturers have
standard products designed for the MAX845, while
some have standard products that can be adapted for
specific customer requirements. Table 1 also lists some
suppliers of suitable magnetic cores.
Table 1. Transformer and Transformer-Core
Suppliers
TRANSFORMERS
TRANSFORMER CORES
Halo Electronics
Magnetics Inc.
Phone: (415) 969-7313
Phone: (412) 282-8282
FAX: (415) 367-7158
FAX: (412) 282-6955
Ask for MAX845 Transformer
Coilcraft
Fair-Rite Products
Phone: (708) 639-6400
Phone: (914) 895-2055
FAX: (708) 639-1469
FAX: (914) 895-2629
Ask for MAX845 Transformer
BH Electronics
Philips Components
Phone: (612) 894-9590
Phone: (401) 762-3800
FAX: (612) 894-9380
FAX: (401) 762-3805, ext. 324
Ask for MAX845 Transformer
Sumida USA
Phone: (708) 956-0666
FAX: (708) 956-0702
12
MMG (Magnetic Materials Group)
Phone: (201) 345-8900
FAX: (201) 345-1172
Amidon Associates
Phone: (714) 850-4660
FAX: (714) 850-1163
An ungapped toroid core must never be allowed to saturate. An empirical way to measure a toroid’s ET product is to wind 20 turns on the bare core and observe
the current waveform on an oscilloscope while driving
the winding with a function generator. Generate a 50%
duty-cycle square wave at a test frequency of 500kHz,
with no DC offset. Gradually increase the driving voltage until the waveform suddenly begins to draw more
current. At this point, the core is saturating, so reduce
the driving voltage until the core just barely stops saturating. The ET product indicated is simply the maximum voltage that can be applied without saturation,
multiplied by 1µs (the time of half of the period of the
input signal). Because the ET product varies linearly
with the number of turns, this test winding can be
scaled up or down to act as a suitable primary for that
particular core.
A gapped core, such as a bobbin or drum core, is not
limited by ET product, but rather by inductance and
winding resistance. The primary inductance must be
high enough to prevent excessive current flow under
light-load conditions, yet low enough that it can be
wound on the core. Good results can be achieved by
using a primary inductance between 50µH and 200µH.
Calculate the number of turns required by using the
manufacturer’s AL (inductance per turn squared) value,
or measure a test winding with an inductance meter.
Inductance varies with the square of the number of turns.
While most MAX845 applications will use a toroid transformer for highest efficiency and lowest EMI, there may
be applications that can utilize less expensive transformers, such as E, I, or U-shaped cores, magnetic
bobbins, or etched windings on a printed circuit board.
Table 1 lists some transformer and core suppliers who
can assist with your magnetics design.
The secondary or secondaries can be scaled to produce
whatever output is required for the application at hand,
taking into account the rectifier topology to be used and
the forward voltage loss of the diodes selected.
Step-by-Step Transformer
Design Procedure
Before starting the design, determine the minimum and
maximum output voltage requirement, the minimum
and maximum load current, the physical size constraints, and the cost budget.
1) Select an appropriate core shape and material from
core vendors’ data sheets; trade-off EMI vs. space
and cost. Since the MAX845’s output waveform is a
square wave, it is rich in harmonics, so choose a
material with low losses at up to several MHz.
______________________________________________________________________________________
Isolated Transformer Driver
for PCMCIA Applications
VIN
3) Determine the number of turns required for the primary winding. For an ungapped toroid, ET product
from center-tap to D1 must be at least 5V-µs. Other
core types must have sufficient inductance to limit
D1 and D2 output current under minimum load conditions, and must not be allowed to saturate.
4) Select a rectifier topology based on performance
requirements (ripple vs. loss, and space required
for secondary winding). Refer to Table 2, Rectifier
Topology Trade-Offs.
5) Work backward from VOUT requirements to determine the secondary to primary turns ratio. Include
losses in the rectifier diodes, and estimate resistive
losses in the windings. For load currents exceeding 150mA, use a voltage step-down transformer to
step up the output current from the MAX845. Do
not exceed the MAX845’s absolute maximum output current rating (200mA).
6) Wind the transformer with the largest diameter wire
that will fit the winding area. Select a wire gauge to
fill the winding aperture as much as possible.
Larger diameter wire has lower resistance per unit
length. Doubling the wire diameter reduces resistive losses by a factor of four.
Bobbin or drum cores suffer from low coupling between
windings. This usually requires bifilar winding for the
two halves of the primary.
Due to the inherent complexity of magnetic circuit
design, it will be necessary to build a prototype and reiterate the design. If necessary, adjust the design by
altering the number of primary or secondary turns, or the
wire gauge. If using a different core material or geometry, evaluate its ET product or AL as described above.
6
VCC
MAX845
2) Use a test winding to measure ET product (if using
an ungapped toroid) and/or AL value for the core.
1
D1
MAX845
GND1 GND2
2
7
8
D2
Figure 11a. 2-Diode Push-Pull
VIN
6
VCC
D1
1
MAX845
GND1 GND2
2
7
D2
8
Figure 11b. 4-Diode Bridge
VIN
6
VCC
D1
1
MAX845
GND1 GND2
2
7
D2
8
Figure 11c. Voltage Doubler
Rectifier Topology
Diodes
Figure 11 shows various rectifier topologies. Refer to
Table 2 for selection criteria. The turns ratio of the transformer must be set to provide the minimum required output voltage at the maximum anticipated load, with the
minimum expected input voltage. In addition, the calculations should allow for worst-case losses in the rectifiers. Since the turns ratio determined in this manner will
ordinarily produce a much higher voltage at the secondary under conditions of high input voltage and/or
light loading, be careful to prevent an overvoltage condition from occurring (see the Output Voltage vs. Load
Current graph in the Typical Operating Characteristics).
Use fast-switching diode rectifiers. Ordinary silicon signal diodes like the 1N914 or 1N4148 may be used for
low output current levels (less than 50mA), but Schottky
diodes have a lower forward voltage drop and should
be used for higher-current applications. Central
Semiconductor has low-current Schottky diodes as
duals in SOT-23 packages (CMPSH-3 series). The
Nihon SB05W05C is a common-cathode dual in a SOT23; it works well in the two-diode full-wave configuration. The Motorola MBR0520 is an excellent choice for
all configurations.
______________________________________________________________________________________
13
MAX845
Isolated Transformer Driver
for PCMCIA Applications
RS
SIMPLE SHUNT ZENER
RS
22k
TL431
5V OUTPUT
22k
PROGRAMMABLE-IC SHUNT REGULATOR (STAND ALONE)
RS
Output Filter Capacitor
1k
22k
2N2907
5V OUTPUT
TL431
22k
PROGRAMMABLE-IC SHUNT REGULATOR WITH DISCRETE PNP
Figure 12. Shunt-Regulator Circuits
Output Regulator
Since the output voltage is not regulated against
changes in the input voltage or load current, an output
voltage regulator may be needed. A series linear regulator gives good performance and reasonably good
efficiency at low cost. A shunt regulator costs less,
occupies less space, and gives adequate performance
for some applications.
Series regulators such as the MAX666, MAX667,
MAX882/MAX883/MAX884, or MAX603/MAX604 simplify designs. Just select one with the desired output voltage and current capability, and connect it.
14
The simplest voltage regulator is the shunt zener shown
in Figure 12. The series resistor (RS) value should be as
high as possible to still deliver the maximum expected
load current with minimum input voltage. Be sure that no
ratings are exceeded at maximum input voltage and
minimum load current conditions; under such conditions,
the zener diode may have to dissipate much more power
than the load. Alternatively, start with the maximum allowable zener dissipation and select the series resistor
under light-load, high-line conditions. Then verify that
there is sufficient output current available with worstcase low input voltage.
For better regulation than the simple shunt zener, consider a shunt regulator IC such as the TL431. This
device behaves like a zener diode whose voltage can
be programmed by a resistor ratio. It can be used as a
stand-alone device or can be boosted above its 150mA
maximum rating without compromising its accuracy by
adding a discrete PNP transistor, as shown in Figure 12.
The input power of a shunt regulator is nearly independent of load, so efficiency at light loads tends to be
worse than it would be with a series regulator.
Ceramic capacitors can be used as output capacitors
because of the lower level of output ripple current. In
applications where output ripple is not critical, a 0.33µF
chip or ceramic capacitor is normally sufficient. Refer to
Table 3 for suggested capacitor suppliers.
In applications sensitive to output-ripple noise, the output filter capacitor (C2) should have a low equivalent
series resistance (ESR) and a low equivalent series
inductance (ESL), and its capacitance should remain
fairly constant over temperature.
Sprague 595D surface-mount solid tantalum capacitors
and Sanyo OS-CON through-hole capacitors are recommended, if space allows, due to their extremely low ESR.
Capacitor ESR usually rises at low temperatures, but OSCON capacitors provide very low ESR below 0°C.
Input Bypass Capacitor
The input bypass capacitor (C1) is not critical. Unlike
switching regulators, the MAX845’s supply current is
fairly constant, and is therefore less dependent on the
input bypass capacitor. A low-cost 0.33µF chip or
ceramic capacitor is normally sufficient for input
bypassing.
______________________________________________________________________________________
Isolated Transformer Driver
for PCMCIA Applications
Table 3. Suggested Capacitor Suppliers
CAPACITOR
TOPOLOGY
2-Diode
Push/Pull
(Figure 11a)
ADVANTAGE
• Only 3 external
components
• Low output ripple
DISADVANTAGE
4-Diode
Bridge
(Figure 11b)
Voltage
Doubler
(Figure 11c)
• Simpler transformer
winding requirements
• Low output ripple
SUPPLIER
Low-ESR 267 Series
Matsuo
USA Phone: (714) 969-2491
FAX: (714) 960-6492
Ceramic
Murata Erie
USA Phone: (800) 831-9172
FAX: (404) 436-3030
Very Low-ESR 595D/293D
Series
Sprague Electric Co.
USA Phone: (603) 224-1961
FAX: (603) 224-1430
• More turns on
transformer
• Single diode drop
MAX845
Table 2. Rectifier Topology Trade-Offs
• 5 external
components
• Higher cost
• 2 diode drops
• 4 external
components
• Fewest turns on
transformer
• Higher output
ripple
• 2 diode drops
___________________Chip Topography
D1
D2
0.085"
(2.159mm)
GND1
GND2
FS
V CC
SD
0.058"
(1.4732mm)
SUBSTRATE CONNECTED TO VCC
TRANSISTOR COUNT: 31
______________________________________________________________________________________
15
8LUMAXD.EPS
________________________________________________________Package Information
SOICN.EPS
MAX845
Isolated Transformer Driver
for PCMCIA Applications
16
______________________________________________________________________________________