LINER LT1683IG

LT1683
Ultralow Noise
Push-Pull DC/DC Controller
DESCRIPTIO
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FEATURES
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The LT ®1683 is a switching regulator controller designed
to lower conducted and radiated electromagnetic interference (EMI). Ultralow noise and EMI are achieved by
controlling the voltage and current slew rates of external
N-channel MOSFET switches. Current and voltage slew
rates can be independently set to optimize harmonic
content of the switching waveforms vs efficiency. The
LT1683 can reduce high frequency harmonic power by as
much as 40dB with only minor losses in efficiency.
The LT1683 utilizes a dual output (push-pull) current
mode architecture optimized for low noise topologies. The
IC includes gate drivers and all necessary oscillator,
control and protection circuitry. Unique error amp circuitry can regulate both positive and negative voltages.
The oscillator may be synchronized to an external clock for
more accurate placement of switching harmonics.
Greatly Reduced Conducted and Radiated EMI
Low Switching Harmonic Content
Independent Control of Output Switch Voltage and
Current Slew Rates
Greatly Reduced Need for External Filters
Dual N-Channel MOSFET Drivers
20kHz to 250kHz Oscillator Frequency
Easily Synchronized to External Clock
Regulates Positive and Negative Voltages
Easier Layout Than with Conventional Switchers
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APPLICATIO S
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Power Supplies for Noise Sensitive Communication
Equipment
EMI Compliant Offline Power Supplies
Precision Instrumentation Systems
Isolated Supplies for Industrial Automation
Medical Instruments
Data Acquisition Systems
Protection features include gate drive lockout for low VIN,
opposite gate lockout, soft-start, output current limit,
short-circuit current limiting, gate drive overvoltage clamp
and input supply undervoltage lockout.
, LTC and LT are registered trademarks of Linear Technology Corporation.
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TYPICAL APPLICATIO
Ultralow Noise 48V to 5V DC/DC Converter
48V
510Ω
0.5W
51k
39µF
63V
MIDCOM 31244
FZT853
10µF
20V
1N4148
OPTIONAL
MBR0530
MBRS340
2N3904
22µH
B
22µH
A 5V/2A
8.2V
68µF
20V
11V
17
3
VIN GCL
23.2k
14
5
976Ω
6
1.2nF
7
16.9k
25k
25k
3.3k
3.3k
1.5k
8
16
15
12
150µF
OS-CON
SHDN
CAP A
V5
GATE A
SYNC
CT
CAP B
LT1683
RT
GATE B
RVSL
CS
5pF
2
5V Output Noise
(Bandwidth = 100MHz)
2×100µF
POSCAP
10pF
200V
MBRS340
1
18
200µVP-P
30pF
19
4 Si9422
A
200µV/DIV
10pF
200V
5pF
B
20mV/DIV
Si9422
0.1Ω
RCSL
PGND
VC
0.22µF 22nF
SS
13
GND
11
FB
NFB
20
7.50k
9
5µs/DIV
30pF
1683 TA01a
2.49k
10
10nF
1683 TA01
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LT1683
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PACKAGE/ORDER I FOR ATIO
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ABSOLUTE
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AXI U RATI GS
(Note 1)
Supply Voltage (VIN) ................................................ 20V
Gate Drive Current ..................................... Internal Limit
V5 Current ................................................. Internal Limit
SHDN Pin Voltage .................................................... 20V
Feedback Pin Voltage (Trans. 10ms) ...................... ±10V
Feedback Pin Current ............................................ 10mA
Negative Feedback Pin Voltage (Trans. 10ms) ........ ±10V
CS Pin .......................................................................... 5V
GCL Pin ..................................................................... 16V
SS Pin .......................................................................... 3V
Operating Junction Temperature Range
(Note 3) ............................................ – 40°C to 125°C
Storage Temperature Range ................. – 65°C to 150°C
Lead Temperature (Soldering, 10 sec).................. 300°C
TOP VIEW
GATE A
1
20 PGND
CAP A
2
19 GATE B
GCL
3
18 CAP B
CS
4
17 VIN
V5
5
16 RVSL
SYNC
6
15 RCSL
CT
7
14 SHDN
RT
8
13 SS
FB
9
12 VC
NFB 10
ORDER PART
NUMBER
LT1683EG
LT1683IG
11 GND
G PACKAGE
20-LEAD PLASTIC SSOP
TJMAX = 150°C, θJA = 110°C/ W
Consult LTC Marketing for parts specified with wider operating temperature ranges.
ELECTRICAL CHARACTERISTICS
The ● denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. VIN = 12V, VC = 0.9V, VFB = VREF, RVSL, RCSL = 16.9k, RT = 16.9k and
other pins open unless otherwise noted.
SYMBOL
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
1.235
1.250
1.265
V
Error Amplifiers
VREF
Reference Voltage
Measured at Feedback Pin
●
IFB
Feedback Input Current
VFB = VREF
●
250
1000
nA
FBREG
Reference Voltage Line Regulation
2.7V ≤ VIN ≤ 20V
●
0.012
0.03
%/V
VNFR
Negative Feedback Reference Voltage
Measured at Negative Feedback Pin
with Feedback Pin Open
●
– 2.56
– 2.500
– 2.45
V
INFR
Negative Feedback Input Current
VNFB = VNFR
– 37
– 25
NFBREG
Negative Feedback Reference Voltage Line Regulation
2.7V ≤ VIN ≤ 20V
gm
Error Amplifier Transconductance
∆IC = ±50µA
●
µA
0.009
0.03
%/V
1100
700
1500
●
2200
2500
µmho
µmho
200
350
µA
200
350
µA
IESK
Error Amp Sink Current
VFB = VREF + 150mV, VC = 0.9V
●
120
IESRC
Error Amp Source Current
VFB = VREF – 150mV, VC = 0.9V
●
120
VCLH
Error Amp Clamp Voltage
High Clamp, VFB = 1V
1.27
V
VCLL
Error Amp Clamp Voltage
Low Clamp, VFB = 1.5V
0.12
V
AV
Error Amplifier Voltage Gain
250
V/V
FBOV
FB Overvoltage Shutdown
Outputs Drivers Disabled
1.47
V
ISS
Soft-Start Charge Current
VSS = 1V
9.0
180
12
µA
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LT1683
ELECTRICAL CHARACTERISTICS
The ● denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. VIN = 12V, VC = 0.9V, VFB = VREF, RVSL, RCSL = 16.9k, RT = 16.9k and
other pins open unless otherwise noted.
SYMBOL
PARAMETER
CONDITIONS
MIN
Oscillator Frequency = 250kHz
290
TYP
MAX
UNITS
Oscillator and Sync
fMAX
Max Switch Frequency
fSYNC
Synchronization Frequency Range
VSYNC
SYNC Pin Input Threshold
RSYNC
SYNC Pin Input Resistance
250
●
0.7
kHz
kHz
1.4
2.0
40
kΩ
45
46
%
10
7.6
10.4
7.9
10.7
8.1
V
V
0.2
0.35
V
Gate Drives (Specifications Apply to Either A or B Unless Otherwise Noted)
DCMAX
Maximum Switch Duty Cycle
RVSL = RCSL = 4.85k,
Osc Frequency = 25kHz
VGON
Gate On Voltage
VIN = 12, GCL = 12
VIN = 12, GCL = 8
VGOFF
Gate Off Voltage
VIN = 12V
IGSO
Max Gate Source Current
VIN = 12V
0.3
A
IGSK
Max Gate Sink Current
VIN = 12V
0.3
A
VINUVLO
Gate Drive Undervoltage Lockout (Note 5)
VGCL = 6.5V, Gates Enabled
●
7.3
7.5
V
Current Sense
tIBL
Switch Current Limit Blanking Time
VSENSE
Sense Voltage Shutdown Voltage
VSENSEF
Sense Voltage Fault Threshold
100
VC Pulled Low
●
86
●
ns
103
120
mV
230
300
mV
Slew Control (for the Following Slew Tests See Test Circuit in Figure 1b)
VSLEWR
Output Voltage Slew Rising Edge
RVSL = RCSL = 17k
26
V/µs
VSLEWF
Output Voltage Slew Falling Edge
RVSL = RCSL = 17k
19
V/µs
VISLEWR
Output Current Slew Rising Edge (CS Pin Voltage)
RVSL = RCSL = 17k
2.1
V/µs
VISLEWF
Output Current Slew Falling Edge (CS Pin Voltage)
RVSL = RCSL = 17k
2.1
V/µs
Supply and Protection
VINMIN
Minimum Input Voltage (Note 4)
VGCL = VIN
●
2.55
3.6
V
IVIN
Supply Current (Note 2)
RVSL = RCSL = 17k, VIN = 12
RVSL = RCSL = 17k, VIN = 20
●
●
25
35
45
55
mA
mA
VSHDN
Shutdown Turn-On Threshold
●
1.31
1.39
1.48
V
∆VSHDN
Shutdown Turn-On Voltage Hysteresis
●
50
110
180
mV
ISHDN
Shutdown Input Current Hysteresis
10
24
35
µA
V5
5V Reference Voltage
6.5V ≤ VIN ≤ 20V, IV5 = 5mA
6.5V ≤ VIN ≤ 20V, IV5 = – 5mA
4.85
4.80
5
5
5.20
5.15
V
V
IV5SC
5V Reference Short-Circuit Current
VIN = 6.5V Source
VIN = 6.5V Sink
10
–10
●
Note 1: Absolute Maximum Ratings are those values beyond which the
life of a device may be impaired.
Note 2: Supply current specification includes loads on each gate as in
Figure 1a. Actual supply currents vary with operating frequency, operating
voltages, V5 load, slew rates and type of external FET.
Note 3: The LT1683E is guaranteed to meet performance specifications
from 0°C to 70°C. Specifications over the –40°C to 125°C operating range
mA
mA
are assured by design, characterization and correlation with statistical
process controls. The LT1683I is guaranteed and tested over the – 40° to
125° operating temperature range.
Note 4: Output gate drivers will be enabled at this voltage. The GCL
voltage will also determine drivers’ activity.
Note 5: Gate drivers are ensured to be on when VIN is greater than the
maximum value.
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LT1683
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TYPICAL PERFOR A CE CHARACTERISTICS
Negative Feedback Voltage and
Input Current vs Temperature
2.480
3.2
1.258
700
2.485
3.0
1.256
650
2.490
2.8
1.254
600
1.252
550
2.495
2.6
1.250
500
2.500
2.4
1.248
450
2.505
2.2
1.246
400
2.510
2.0
1.244
350
1.242
300
2.515
1.8
1.240
–50 –25
0
NEGATIVE FEEDBACK VOLTAGE (V)
750
2.520
–50 –25
250
25 50 75 100 125 150
TEMPERATURE (°C)
0
1.6
25 50 75 100 125 150
TEMPERATURE (°C)
1683 G01
1683 G02
Feedback Overvoltage Shutdown
vs Temperature
Error Amp Output Current vs
Feedback Pin Voltage from Nominal
500
1900
400
1800
300
1700
200
1.55
1.50
1.45
1.40
1.35
1.30
1.25
1.20
–50 –25
0
25 50 75 100 125 150
TEMPERATURE (°C)
CURRENT (µA)
2000
1.65
TRANSCONDUCTANCE (µmho)
FEEDBACK VOLTAGE (V)
Error Amp Transconductance vs
Temperature
1.70
1.60
1600
1500
1400
–300
1100
–400
25 50 75 100 125 150
TEMPERATURE (°C)
1683 G03
SHDN Pin On and Off Thresholds
vs Temperature
1.50
240
220
0.8
0.6
0.4
FAULT
1.45
SHDN PIN VOLTAGE (V)
CS PIN VOLTAGE (mV)
VC PIN VOLTAGE (V)
1683 G05
CS Pin Trip and CS Fault Voltage
vs Temperature
1.2
200
180
160
140
120
ON
1.40
1.35
1.30
TRIP
0.2
0
–50 –25
–500
–400 –300 –200 –100 0 100 200 300 400
FEEDBACK PIN VOLTAGE FROM NOMINAL (mV)
1683 G04
VC Pin Threshold and Clamp
Voltage vs Temperature
1.0
125°C
–100
–200
0
25°C
0
1200
1000
–50 –25
–40°C
100
1300
1.4
OFF
100
0
25 50 75 100 125 150
TEMPERATURE (°C)
1683 G06
NFB INPUT CURRENT (µA)
1.260
FB INPUT CURRENT (nA)
FEEDBACK VOLTAGE (V)
Feedback Voltage and Input
Current vs Temperature
80
–50 –25
0
25 50 75 100 125 150
TEMPERATURE (°C)
1683 G07
1.25
–50 –25
0
25 50 75 100 125 150
TEMPERATURE (°C)
1683 G08
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TYPICAL PERFOR A CE CHARACTERISTICS
SHDN Pin Hysteresis Current vs
Temperature
CS Pin to VC Pin Transfer
Function
VIN Current vs Temperature
27
1.6
24
21
19
17
20
VIN = 12 RCSL, RVSL = 5.7k
18
VIN = 20 RCSL, RVSL = 17k
16
VIN = 12 RCSL, RVSL = 17k
14
10
–50 –25
25 50 75 100 125 150
TEMPERATURE (°C)
0
GATE DRIVE A/B PIN VOLTAGE (V)
PERCENT OF MAX CS VOLTAGE
VC PIN = 0.9V
TA = 25°C
90
80
70
60
20
30
DUTY CYCLE (%)
40
50
6.5
0.50
10.6
6.4
0.45
GCL = 12V
10.5
6.2
10.3
6.1
VIN = 12V
NO LOAD
10.2
6.0
5.9
10.1
10.0
5.8
GCL = 6V
9.90
5.7
9.80
5.6
9.70
–50 –25
0
9.3
0.25
0.20
0.15
0.10
0.05
5.5
25 50 75 100 125 150
TEMPERATURE (°C)
0
–50 –25
V5 Voltage vs Load Current
5.08
5.06
8.7
8.5
8.3
8.1
7.9
6.4
7.7
0
25 50 75 100 125 150
TEMPERATURE (°C)
1683 G15
25 50 75 100 125 150
TEMPERATURE (°C)
SS VOLTAGE = 0.9V
8.9
6.5
6.3
–50 –25
0
1683 G14
V5 PIN VOLTAGE (V)
6.6
VIN = 12V
NO LOAD
0.30
9.1
SS PIN CURRENT (µA)
7.1
120
0.35
9.5
6.7
100
0.40
Soft-Start Current vs Temperature
GCL = 6V
6.8
40
60
80
CS PIN VOLTAGE (mV)
1683 G13
7.3
VIN PIN VOLTAGE (V)
6.3
10.4
Gate Drive Undervoltage Lockout
Voltage vs Temperature
6.9
20
Gate Drive A/B Low Voltage vs
Temperature
10.7
1683 G12
7.0
0
1683 G11
Gate Drive A/B High Voltage vs
Temperature
110
10
0.6
1683 G10
Slope Compensation
0
0.8
0
25 50 75 100 125 150
TEMPERATURE (°C)
1683 G09
100
1.0
0.2
GATE DRIVE A/B PIN VOLTAGE (V)
0
1.2
0.4
12
15
–50 –25
7.2
VC PIN VOLTAGE (V)
VIN CURRENT (mA)
22
23
50
TA = 25°C
1.4
25
SHDN PIN CURRENT (µA)
WITH NO EXTERNAL MOSFETs
7.5
–50 –25
T = 125°C
5.04
5.02
T = 25°C
5.00
T = –40°C
4.98
0
25 50 75 100 125 150
TEMPERATURE (°C)
1683 G16
4.96
–15
–10
–5
0
5
LOAD CURRENT (mA)
10
15
1683 G17
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LT1683
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Part Supply
V5 (Pin 5): This pin provides a 5V output that can sink or
source 10mA for use by external components. V5 source
current comes from VIN . Sink current goes to GND. VIN
must be greater than 6.5V in order for this voltage to be in
regulation. If this pin is used, a small capacitor (<1µF) may
be placed on this pin to reduce noise. This pin can be left
open if not used.
GND (Pin 11): Signal Ground. The internal error amplifier,
negative feedback amplifier, oscillator, slew control circuitry, V5 regulator, current sense and the bandgap reference are referred to this ground. Keep the connection to
this pin, the feedback divider and VC compensation network free of large ground currents.
SHDN (Pin 14): The shutdown pin can disable the switcher.
Grounding this pin will disable all internal circuitry.
Increasing SHDN voltage will initially turn on the internal
bandgap regulator. This provides a precision threshold for
the turn on of the rest of the IC. As SHDN increases past
1.39V the internal LDO regulator turns on, enabling the
control and logic circuitry.
24µA of current is sourced out of the pin above the turn on
threshold. This can be used to provide hysteresis for the
shutdown function. The hysteresis voltage will be set by
the Thevenin resistance of the resistor divider driving this
pin times the current sourced out. Above approximately
2.1V the hysteresis current is removed. There is approximately 0.1V of voltage hysteresis on this pin as well.
The pin can be tied high (to VIN for instance).
VIN (Pin 17): Input Supply. All supply current for the part
comes from this pin including gate drives and V5 regulator. Charge current for gate drives can produce current
pulses of hundreds of milliamperes. Bypass this pin with
a low ESR capacitor.
When VIN is below 2.55V the part will go into supply
undervoltage lockout where the gate drivers are driven
low. This, along with gate drive undervoltage lockout,
prevents unpredictable behavior during power up.
PGND (Pin 20): Power Driver Ground. This ground comes
from the MOSFET gate drivers. This pin can have several
hundred milliamperes of current on it when the external
MOSFETs are being turned off.
Oscillator
SYNC (Pin 6): The SYNC pin can be used to synchronize
the part to an external clock. The oscillator frequency
should be set close to the external clock frequency.
Synchronizing the clock to an external reference is useful
for creating more stable positioning of the switcher voltage and current harmonics. This pin can be left open or
tied to ground if not used.
CT (Pin 7): The oscillator capacitor pin is used in conjunction with RT to set the oscillator frequency. For RT = 16.9k:
COSC(nf) = 129/fOSC(kHz)
RT (Pin 8): The oscillator resistor pin is used to set the
charge and discharge currents of the oscillator capacitor.
The nominal value is 16.9k. It is possible to adjust this
resistance ±25% to set oscillator frequency more accurately.
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LT1683
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Gate Drive
GATE A, GATE B (Pins 1, 19): These pins connect to the
gates of the external N-channel MOSFETs. GATE␣ A and
GATE␣ B turn on with alternate clock cycles. These drivers
are capable of sinking and sourcing at least 300mA.
The GCL pin sets the upper voltage of the gate drive. The
gate pins will not be activated until VIN reaches a minimum
voltage as defined by the GCL pin (gate undervoltage
lockout).
The gate drive outputs have current limit protection to safe
guard against accidental shorts.
If the gate drive voltage is greater than about 1V the
opposite gate drive is inhibited thus preventing cross
conduction.
GCL (Pin 3): This pin sets the maximum gate voltage to the
GATE␣ A and GATE␣ B pins to the MOSFET gate drives. This
pin should be either tied to a Zener, a voltage source or VIN.
If the pin is tied to a Zener or a voltage source, the
maximum gate drive voltage will be approximately
VGCL – 0.2V. If it is tied to VIN, the maximum gate voltage
is approximately VIN – 1.6.
Approximately 50µA of current can be sourced from this
pin if VGCL < VIN – 0.8V.
This pin also controls undervoltage lockout of the gate
drives. If the pin is tied to a Zener or voltage source, the
gate drive will not be enabled until VIN > VGCL + 0.8V. If this
pin is tied to VIN, then undervoltage lockout is disabled.
There is an internal 19V Zener tied from this pin to ground
to provide a fail-safe for maximum gate voltage.
Slew Control
CAP A, CAP B (Pins 2, 18): These pins are the feedback
nodes for the external voltage slewing capacitors. Normally a small 1pf to 5pf capacitor is connected from this
pin to the drain of its respective MOSFET.
The voltage slew rate is inversely proportional to this
capacitance and proportional to the current that the part
will sink and source on this pin. That current is inversely
proportional to RVSL.
RCSL (Pin 15): A resistor to ground sets the current slew
rate for the external drive MOSFETs during switching. The
minimum resistor value is 3.3k and the maximum value is
68k. The time to slew between on and off states of the
MOSFET current will determine how the di/dt related
harmonics are reduced. This time is proportional to RCSL
and RS (the current sense resistor) and maximum current.
Longer times produce a greater reduction of higher frequency harmonics.
RVSL (Pin 16): A resistor to ground sets the voltage slew
rate for the drains of the external drive MOSFETs. The
minimum resistor value is 3.3k and the maximum value is
68k. The time to slew between on and off states on the
MOSFET drain voltage will determine how harmonics are
reduced from this source. This time is proportional to
RVSL, CVA/B and the input voltage. Longer times produce
more rolloff of harmonics. CVA/B is the equivalent capacitance from CAP A or B to the drain of the MOSFET.
Switch Mode Control
SS (Pin 3): The SS pin allows for ramping of the switch
current threshold at startup. Normally a capacitor is placed
on this pin to ground. An internal 9µA current source will
charge this capacitor up. The voltage on the VC pin cannot
exceed the voltage on SS. Thus peak current will ramp up
as the SS pin ramps up. During a short circuit fault the SS
pin will be discharged to ground thus reinitializing softstart.
When SS is below the VC clamp voltage the VC pin will
closely track the SS pin.
This pin can be left open if not used.
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CS (Pin 4): This is the input to the current sense amplifier.
It is used for both current mode control and current
slewing of the external MOSFETs. Current sense is accomplished via a sense resistor (RS) connected from the
sources of the external MOSFETs to ground. CS is connected to the top of RS. Current sense is referenced to the
GND pin.
NFB (Pin 10): The negative feedback pin is used for
sensing a negative output voltage. The pin is connected to
the inverting input of the negative feedback amplifier
through a 100k source resistor. The negative feedback
amplifier provides a gain of –0.5 to the FB pin. The nominal
regulation point would be –2.5V on NFB. This pin should
be left open if not used.
The switch maximum operating current will be equal to
0.1V/RS. At CS = 0.1V, the gate drivers will be immediately
turned off (no slew control).
If NFB is being used then overvoltage protection will occur
at 0.44V below the NFB regulation point.
If CS = 0.22V in addition to the drivers being turned off, VC
and SS will be discharged to ground (short-circuit protection). This will hasten turn off on subsequent cycles.
VC (Pin 12): The compensation pin is used for frequency
compensation and current limiting. It is the output of the
error amplifier and the input of the current comparator.
Loop frequency compensation can be performed with an
RC network connected from the VC pin to ground. The
voltage on VC is proportional to the switch peak current.
The normal range of voltage on this pin is 0.25V to 1.27V.
However, during slope compensation the upper clamp
voltage is allowed to increase with the compensation.
FB (Pin 9): The feedback pin is used for positive voltage
sensing. It is the inverting input to the error amplifier. The
noninverting input of this amplifier connects internally to
a 1.25V reference.
If the voltage on this pin exceeds the reference by 220mV,
then the output drivers will immediately turn off the
external MOSFETs (no slew control). This provides for
output overvoltage protection
At NFB < –1.8 current sense blanking will be disabled.
During a short-circuit fault the VC pin will be discharged to
ground.
When this input is below 0.9V then the current sense
blanking will be disabled. This will assist start up.
TEST CIRCUITS
0.9A
20mA
5pF
5pF
IN5819
IN5819
CAP A/CAP B
CAP A/CAP B
ZVN3306A
GATE A/GATE B
+
–
10
GATE A/GATE B
Si4450DY
CS
+
–
10
2
0.1
1683 F01a
Figure 1a. Typical Test Circuitry
1683 F01b
Figure 1b. Test Circuit for Slew
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LT1683
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BLOCK DIAGRA
VIN
CIN
RCSL
SHDN
VIN
V5
RVSL
RCSL
RVSL
TO
DRIVERS
REGULATOR
+
NEGATIVE
FEEDBACK
AMP
VREG
–
NFB
100k
GCL
50k
CVA
CAP A
GATE A
+
FB
–
ERROR
AMP
CVB
SLEW
CONTROL
+
MA
CAP B
1.25V
GATE B
CVC
VC
MB
PGND
–
CSS
SS
CS
+
COMP
SENSE
AMP
+
RSENSE
–
S
RT
Q
FF
RT
R
OSCILLATOR
CT
CT
T
Q
FF
QB
SYNC
SUB
GND
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In noise sensitive applications switching regulators tend
to be ruled out as a power supply option due to their
propensity for generating unwanted noise. When switching supplies are required due to efficiency or input/output
constraints, great pains must be taken to work around the
noise generated by a typical supply. These steps may
include pre and post regulator filtering, precise synchronization of the power supply oscillator to an external clock,
synchronizing the rest of the circuit to the power supply
oscillator or halting power supply switching during noise
sensitive operations. The LT1683 greatly simplifies the
task of eliminating supply noise by enabling the design of
an inherently low noise switching regulator power supply.
The LT1683 is a fixed frequency, current mode switching
regulator with unique circuitry to control the voltage and
current slew rates of the output switches. Current mode
control provides excellent AC and DC line regulation and
simplifies loop compensation.
Slew control capability provides much greater control
over the power supply components that can create conducted and radiated electromagnetic interference. Compliance with EMI standards will be an easier task and will
require fewer external filtering components.
The LT1683 uses two external N-channel MOSFETs as the
power switches. This allows the user to tailor the drive
conditions to a wide range of voltages and currents.
CURRENT MODE CONTROL
Referring to the block diagram. A switching cycle begins
with an oscillator discharge pulse, which resets the RS
flip-flop, turning on one of the external MOSFET drivers.
The switch current is sensed across the external sense
resistor and the resulting voltage is amplified and compared to the output of the error amplifier (VC pin). The
driver is turned off once the output of the current sense
amplifier exceeds the voltage on the VC pin. In this way
pulse by pulse current limit is achieved. The toggle flipflop ensures that the two MOSFETs are enabled on alternate clock cycles. Internal slope compensation is provided
to ensure stability under high duty cycle conditions.
Output regulation is obtained using the error amp to set
the switch current trip point. The error amp is a
transconductance amplifier that integrates the difference
between the feedback output voltage and an internal 1.25V
reference. The output of the error amp adjusts the switch
current trip point to provide the required load current at the
desired regulated output voltage. This method of controlling current rather than voltage provides faster input
transient response, cycle-by-cycle current limiting for
better output switch protection and greater ease in compensating the feedback loop. The VC pin is used for loop
compensation and current limit adjustment. During normal operation the VC voltage will be between 0.25V and
1.27V. An external clamp on VC or SS may be used for
lowering the current limit.
The negative voltage feedback amplifier allows for direct
regulation of negative output voltages. The voltage on the
NFB pin gets amplified by a gain of – 0.5 and driven on to
the FB input, i.e., the NFB pin regulates to –2.5V while the
amplifier output internally drives the FB pin to 1.25V as in
normal operation. The negative feedback amplifier input
impedance is 100k (typ) referred to ground.
Soft-Start
Control of the switch current during start up can be
obtained by using the SS pin. An external capacitor from
SS to ground is charged by an internal 9µA current source.
The voltage on VC cannot exceed the voltage on SS. Thus
as the SS pin ramps up the VC voltage will be allowed to
ramp up. This will then provide for a smooth increase in
switch maximum current. SS will be discharged as a result
of the CS voltage exceeding the short circuit threshold of
approximately 0.22V.
Slew Control
Control of output voltage and current slew rates is achieved
via two feedback loops. One loop controls the MOSFET
drain dV/dt and the other loop controls the MOSFET dI/dt.
The voltage slew rate uses an external capacitor between
CAP A or CAP B and the respective MOSFET drain. These
integrating caps close the voltage feedback loop. The
external resistor RVSL sets the current for the integrator.
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The voltage slew rate is thus inversely proportional to both
the value of capacitor and RVSL.
The current slew feedback loop consists of the voltage
across the external sense resistor, which is internally
amplified and differentiated. The derivative is limited to a
value set by RCSL. The current slew rate is thus inversely
proportional to both the value of sense resistor and RCSL.
The two control loops are combined internally so that a
smooth transition from current slew control to voltage
slew control is obtained. When turning on, the driver
current will slew before voltage. When turning off, voltage
will slew before current. In general it is desirable to have
RVSL and RCSL of similar value.
Internal Regulator
Most of the control circuitry operates from an internal 2.4V
low dropout regulator that is powered from VIN. The
internal low dropout design allows VIN to vary from 2.7V
to 20V with stable operation of the controller. When SHDN
< 1.3V the internal regulator is completely disabled.
5V Regulator
A 5V regulator is provided for powering external circuitry.
This regulator draws current from VIN and requires VIN to
be greater than 6.5V to be in regulation. It can sink or
source 10mA. The output is current limited to prevent
against destruction from accidental short circuits.
Safety and Protection Features
There are several safety and protection features on the
chip. The first is overcurrent limit. Normally the gate
drivers will go low when the output of the internal sense
amplifier exceeds the voltage on the VC pin. The VC pin is
clamped such that maximum output current is attained
when the CS pin voltage is 0.1V. At that level the outputs
will be immediately turned off (no slew). The effect of this
control is that the output voltage will foldback with
overcurrent.
In addition, if the CS voltage exceeds 0.22V, the VC and SS
pins will be discharged to ground also, resetting the softstart function. Thus if a short is present this will allow for
faster MOSFET turnoff and less MOSFET stress.
If the voltage on the FB pin exceeds regulation by approximately 0.22V, the outputs will immediately go low. The
implication is that there is an overvoltage fault.
The voltage on GCL determines two features. The first is
the maximum gate drive voltage. This will protect the
MOSFET gate from overvoltage.
With GCL tied to a Zener or an external voltage source then
the maximum gate driver voltage is approximately
VGCL␣ – 0.2V. If GCL is tied to VIN, then the maximum gate
voltage is determined by VIN and is approximately
VIN – 1.6V. There is an internal 19V Zener on the GCL pin
that prevents the gate driver pin from exceeding approximately 19V.
In addition, the GCL voltage determines undervoltage
lockout of the gate drives. This feature disables the gate
drivers if VIN is too low to provide adequate voltage to turn
on the MOSFETs. This is helpful during start up to insure
the MOSFETs have sufficient gate drive to saturate.
If GCL is tied to a voltage source or Zener less than 6.8V,
the gate drivers will not turn on until VIN exceeds GCL
voltage by 0.8V. For VGCL above 6.5V, the gate drives are
insured to be off for VIN < 7.3V and they will be turned on
by VGCL + 0.8V.
If GCL is tied to VIN, the gate drivers are always enabled
(undervoltage lockout is disabled).
When driving a push pull transformer, it is important to
make sure that both drivers are not on at the same time.
Even though runaway cannot occur under such cross
conduction with this chip because current slew is regulated, increased current would be possible. This chip has
opposite gate lockout whereby when one MOSFET is on
the other MOSFET cannot be turned on until the gate of the
first drops below 1V. This insures that cross conduction
will not occur.
The gate drives have current limits for the drive currents.
If the sink or source current is greater than 300mA then the
current will be limited.
The V5 regulator also has internal current limiting that will
only guarantee ±10mA output current.
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There is also an on chip thermal shutdown circuit that will
turn off the outputs in the event the chip temperature rises
to dangerous levels. Thermal shutdown has hysteresis
that will cause a low frequency (<1kHz) oscillation to occur
as the chip heats up and cools down.
The chip has an undervoltage lockout feature that will
force the gate drivers low in the event that VIN drops below
2.5V. This insures predictable behavior during start up and
shut down. SHDN can be used in conjuction with an
external resistor divider to completely disable the part if
the input voltage is too low. This can be used to insure
adequate voltage to reliably run the converter. See the
section in Applications Information.
Table 1 summarizes these features.
Table 1. Safety and Protection Features
FEATURE
FUNCTION
EFFECT on GATE DRIVERS SLEW CONTROL EFFECT on VC, SS
Maximum Current Fault
Turn Off FETs at Maximum
Switch Current (VSENSE = 0.1)
Immediately Goes Low
Overridden
None
Short-Circuit Fault
Turn Off FETs and Reset VC
for Short-Circuit (VSENSE = 0.2)
Immediately Goes Low
Overridden
Discharge VC, SS
to GND
Overvoltage Fault
Turn Off Drivers If FB > VREG + 0.22V
(Output Overvoltage)
Immediately Goes Low
Overridden
None
GCL Clamp
Set Max Gate Voltage to Prevent
FET Gate Breakdown
Limits Max Voltage
None
None
Gate Drive
Undervoltage Lockout
Disable Gate Drives When VIN
Is Too Low. Set Via GCL Pin
Immediately Goes Low
Overridden
None
Thermal Shutdown
Turn Off Drivers If Chip
Temperature Is Too Hot
Immediately Goes Low
Overridden
None
Opposite Gate Lockout
Prevents Opposite Driver from
Turning on Until Driver Is Off
(Cross Conduction in Transformer)
Inhibits Turn On of
Opposite Driver
None
None
VIN Undervoltage Lockout
Disable Part When VIN ≅ 2.55V
Immediately Goes Low
Overridden
None
Gate Drive Source and Sink Current Limit
Limit Gate Drive Current
Limit Drive Current
None
None
V5 Source/Sink Current Limit
Limit Current from V5
None
None
None
Shutdown
Disable Part When SHDN <1.3V
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Reducing EMI from switching power supplies has traditionally invoked fear in designers. Many switchers are
designed solely on efficiency and as such produce waveforms filled with high frequency harmonics that then
propagate through the rest of the system.
The LT1683 provides control over two of the more important variables for controlling EMI with switching inductive
loads: switch voltage slew rate and switch current slew
rate. The use of this part will reduce noise and EMI over
conventional switch mode controllers. Because these
variables are under control, a supply built with this part will
exhibit far less tendency to create EMI and less chance of
encountering problems during production.
Nominally RT should be 16.9k. Since it sets up current, its
temperature coefficient should be selected to compliment
the capacitor. Ideally, both should have low temperature
coefficients.
Oscillator frequency is important for noise reduction in
two ways. First the lower the oscillator frequency the lower
the waveform’s harmonics, making it easier to filter them.
Second the oscillator will control the placement of the
output voltage harmonics which can aid in specific problems where you might be trying to avoid a certain frequency bandwidth.
Oscillator Sync
It is beyond the scope of this data sheet to get into EMI
fundamentals. Application Note 70 contains much information concerning noise in switching regulators and
should be consulted.
If a more precise frequency is desired (e.g., to accurately
place harmonics) the oscillator can be synchronized to an
external clock. Set the RC timing components for an
oscillator frequency 10% lower than the desired sync
frequency.
Oscillator Frequency
Drive the SYNC pin with a square wave (with greater than
1.4V amplitude). The rising edge of the sync square wave
will initiate clock discharge. The sync pulse should have a
minimum pulse width of 0.5µs.
The oscillator determines the switching frequency and
therefore the fundamental positioning of all harmonics.
The use of good quality external components is important
to ensure oscillator frequency stability. The oscillator is of
a sawtooth design. A current defined by external resistor
RT is used to charge and discharge the capacitor CT . The
discharge rate is approximately ten times the charge rate.
By allowing the user to have control over both components, trimming of oscillator frequency can be more easily
achieved.
The external capacitance CT is chosen by:
2180
C T (nF ) =
f(kHz)• RT (kΩ)
where f is the desired oscillator frequency in kHz. For RT
equal to 16.9k, this simplifies to:
C T (nF ) =
129
f(kHz)
Be careful in sync’ing to frequencies much different from
the part since the internal oscillator charge slope determines slope compensation. It would be possible to get into
subharmonic oscillation if the sync doesn’t allow for the
charge cycle of the capacitor to initiate slope compensation. In general, this will not be a problem until the sync
frequency is greater than 1.5 times the oscillator free-run
frequency.
Slew Rate Setting
The primary reason to use this part is to gain advantage of
lower EMI and noise due to slew control. The rolloff in
higher frequency harmonics has its theoretical basis with
two primary components. First, the clock frequency sets
the fundamental positioning of harmonics and second, the
associated normal frequency rolloff of harmonics.
e.g., CT = 1.29nF for f = 100kHz
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This part creates a second higher frequency rolloff of
harmonics that inversely depends on the slew time, the
time that voltage or current spends between the off state
and on state. This time is adjustable through the choice of
the slew resistors, the external resistors to ground on the
RVSL and RCSL pins and the external components used for
the external voltage feedback capacitors CAV, CBV (from
CAP A or CAP B to their respective MOSFET drains) and the
sense resistor. Lower slew rates (longer slew times, lower
frequency for harmonics rolloff) is created with higher
values of RVSL, RCSL, CAV, CBV and the current sense
resistor
Setting the voltage and current slew rates should be done
empirically. The most practical way of determining these
components is to set CAV, CBV and the sense resistor
value. Then, start by making RVSL, RCSL each a 50k
resistor pot in series with 3.3k. Starting from the lowest
resistor setting (fast slew) adjust the pots until the noise
level meets your guidelines. Note that slower slewing
waveforms will dissipate more power so that efficiency
will drop. You can monitor this as you make your slew
adjustment by measuring input and output voltage and
their respective currents. Monitor the MOSFET temperature as slew rates are slowed. These components will heat
up as efficiency decreases.
Measuring noise should be done carefully. It is easy to
introduce noise by poor measurement techniques. Consult AN70 for recommended measurement techniques.
Keeping probe ground leads very short is essential.
Usually it will be desirable to keep the voltage and current
slew resistors approximately the same. There are circumstances where a better optimization can be found by
adjusting each separately, but as these values are separated further, a loss of independence of control may occur.
It is possible to use a single slew setting resistor. In this
case the RVSL and RCSL pins are tied together. A resistor
with a value of 1.8k to 34k (one half the individual resistors) can then be tied from these pins to ground.
In general only the RCSL value will be available for adjustment of current slew. The current slew time does also
depend on the current sense resistor but this resistor is
normally set with consideration of the maximum current
in the MOSFETs.
Setting the voltage slew also involves selection of the
capacitors CAV, CBV. The voltage slew time is proportional
to the output voltage swing (basically input voltage), the
external voltage feedback capacitor and the RVSL value.
Thus at higher input voltages smaller capacitors will be
used with lower RVSL values. For a starting point use
Table␣ 2.
Table 2
INPUT VOLTAGE
CAPACITOR VALUE
< 25V
5pF
50V
2.5pF
100V
1pF
Smaller value capacitors can be made in two ways. The
first is simply combining two capacitors in series. The
equivalent capacitance is then (C1 • C2)/(C1 + C2).
The second method makes use of a capacitor divider. Care
should be taken that the voltage ratings of the capacitors
satisfy the full voltage swing (2x input voltage for pushpull configurations) thus essentially the same rating as the
MOSFETs.
MOSFET DRAIN
C2
C1
CAP A OR B
C3
1683 F02
Figure 2
The equivalent slew capacitance for Figure 2 is (C1 • C2)/
(C1 + C2 + C3).
Positive Output Voltage Setting
Sensing of a positive output voltage is usually done using
a resistor divider from the output to the FB pin. The
positive input to the error amp is connected internally to a
1.25V bandgap reference. The FB pin will regulate to this
voltage.
Referring to Figure 3, R1 is determined by:
V

R1 = R2  OUT − 1
 1.25 
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The FB bias current represents a small error and can
usually be ignored for values of R1||R2 up to 10k.
One word of caution, sometimes a feedback zero is added
to the control loop by placing a capacitor across R1. If the
feedback capacitively pulls the FB pin above the internal
regulator voltage (2.4V), output regulation may be disrupted. A series resistance with the feedback pin can
eliminate this potential problem. There is an internal clamp
on FB that clamps at 0.7V above the regulation voltage that
should also help prevent this problem.
R1
VOUT
FB PIN
R2
1683 F03
Figure 3
Negative Output Voltage Setting
Negative output voltage can be sensed using the NFB pin.
In this case regulation will occur when the NFB pin is at
–2.5V. The nominal input bias current for the NFB is –25µA
(INFB), which needs to be accounted for in setting up the
divider.
Referring to Figure 4, R1 is chosen such that:
 VOUT − 2.5 
R1 = R2 

 2.5 + R2 • 25µA 


Shutdown
If SHDN is pulled low, the regulator will turn off. As the
SHDN pin voltage is increased from ground the internal
bandgap regulator will be powered on. This will set a 1.39V
threshold for turn on of the internal regulator that runs
most of the control circuitry of the regulator. Note after the
control circuitry powers on, gate driver activity will depend
on the voltage of VIN with respect to the voltage on GCL.
As the SHDN pin enables the internal regulator a 24µA
current will be sourced from the pin that can provide
hysteresis for undervoltage lockout. This hysteresis can
be used to prevent part shutdown due to input voltage sag
from an initial high current draw.
In addition to the current hysteresis, there is also approximately 100mV of voltage hysteresis on the SHDN pin.
When the SHDN pin is greater than 2.2V, the hysteretic
current from the part will be reduced to essentially zero.
If a resistor divider is used to set the turn on threshold then
the resistors are determined by the following equations.
A suggested value for R2 is 2.5k. The NFB pin is normally
left open if the FB pin is being used.
R1
–VOUT
NFB PIN
INFB
LT1683 will act to prevent either output from going
beyond its set output voltage. The highest output (lightest
load) will dominate control of the regulator. This technique
would prevent either output from going unregulated high
at no load. However, this technique will also compromise
output load regulation.
R2
1683 F04
 RA + RB 
VIN
VON = 
 • VSHDN
 RB 


∆VSHDN
VHYST = RA • 
+ ISHDN

 RA RB


Certain applications may benefit from sensing both positive and negative output voltages. When doing this each
output voltage resistor divider is individually set as previously described. When both FB and NFB pins are used, the
SHDN
RB
Reworking these equations yields:
Figure 4
Dual Polarity Output Voltage Sensing
RA
RA =
RB =
(VHYST • VSHDN − VON • ∆VSHDN)
(ISHDN • VSHDN)
(VHYST • VSHDN − VON • ∆VSHDN)
[I
SHDN • (VON
]
− VSHDN)
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So if we wanted to turn on at 20V with 2V of hysteresis:
2V • 1.39V − 20V • 0.1V
= 23.4k
24µA • 1.39V
2V • 1.39V − 20V • 0.1V
RB =
= 1.75k
24µA • (20V − 1.39V)
RA =
Resistor values could be altered further by adding Zeners
in the divider string. A resistor in series with SHDN pin
could further change hysteresis without changing turn on
voltage.
Frequency Compensation
Loop frequency compensation is accomplished by way of
a series RC network on the output of the error amplifier
(VC␣ pin).
VC PIN
RVC
2k
CVC2
4.7nF
CVC
0.01µF
1683 F06
Figure 6
Referring to Figure 6, the main pole is formed by capacitor
CVC and the output impedance of the error amplifier
(approximately 400kΩ). The series resistor RVC creates a
“zero” which improves loop stability and transient response. A second capacitor CVC2, typically one-tenth the
size of the main compensation capacitor, is sometimes
used to reduce the switching frequency ripple on the VC
pin. VC pin ripple is caused by output voltage ripple
attenuated by the output divider and multiplied by the error
amplifier. Without the second capacitor, VC pin ripple is:
VCPINRIPPLE =
1.25 • VRIPPLE • gm • RVC
VOUT
where VRIPPLE = Output ripple (VP-P )
gm = Error amplifier transconductance
RVC = Series resistor on VC pin
VOUT = DC output voltage
To prevent irregular switching, VC pin ripple should be
kept below 50mVP-P . Worst-case VC pin ripple occurs at
maximum output load current and will also be increased if
poor quality (high ESR) output capacitors are used. The
addition of a 0.0047µF capacitor for CVC2 pin reduces
switching frequency ripple to only a few millivolts. A low
value for RVC will also reduce VC pin ripple, but loop phase
margin may be inadequate.
Setting Current Limit
The sense resistor sets the value for maximum operating
current. When the CS pin voltage is 0.1V the gate drivers
will immediately go low (no slew control). Therefore the
sense resistor value should be set to RS = 0.1V/ISW(PEAK),
where ISW(PEAK) is the peak current in the MOSFETs.
ISW(PEAK) will depend on the topology and component
values and tolerances. Certainly it should be set below the
saturation current value for the transformer.
If CS pin voltage is 0.22V in addition to the drivers going
low, VC and SS will be discharged to ground. This is to
provide additional protection in the event of a short circuit.
By discharging VC and SS the MOSFET will not be stressed
as hard on subsequent cycles since the current trip will be
set lower.
Turn off of the MOSFETs will normally be inhibited for
about 100ns at the start of every turn on cycle. This is to
prevent noise from interfering with normal operation of
the controller. This current sense blanking does not prevent the outputs from be turned off in the event of a fault.
Slewing of the gate voltage effectively provides additional
blanking.
Traces to the SENSE resistor should be kept short and
wide to minimize resistance and inductance.
Soft-Start
The soft-start pin is used to provide control of switching
current during startup. The max voltage on the VC pin is
approximately the voltage on the SS pin. A current source
will linearly charge a capacitor on the SS pin. The VC pin
voltage will thus ramp also. The approximate time for the
voltage on these pins to ramp is (1.31V/9µA) • CSS or
approximately 146ms per µF.
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The soft-start current will be initiated as soon as the part
turns on. Soft-start will be reinititated after a short-circuit
fault.
ISW = Maximum switch current
VOUT = Desired output voltage
IOUT = Output current
Thermal Considerations
f = Oscillator frequency
Most of the IC power dissipation is derived from the VIN
pin. The VIN current depends on a number of factors
including: oscillator frequency; loads on V5; slew settings;
gate charge current. Additional power is dissipated if V5
sinks current and during the MOSFET gate discharge.
VF = Forward drop of the rectifier
The power dissipation in the IC will be the sum of:
1) The RMS VIN current times VIN
2) V5 RMS sink current times 5V
Duty cycle is the major defining equation for this topology.
Note that the output L and C basically filter the chopped
voltage so duty cycle controls output voltage. N is the
turns ratio of the transformer. The turns ratio must be
large enough to ensure that the transformer can put out a
voltage equal to the output voltage plus the diode under
minimum input conditions. Note the transformer operates
at half the oscillator frequency (f).
3) The gate drive’s RMS discharge current times voltage
Because of the strong VIN component it is advantageous
to operate the LT1683 at as low a VIN as possible.
It is always recommended that package temperature be
measured in each application. The part has an internal
thermal shutdown to minimize the chance of IC destruction but this should not replace careful thermal design.
The thermal shutdown feature does not protect the external MOSFETs. A separate analysis must be done for those
devices to insure that they are operating within safe limits.
Once IC power dissipation, PDIS, is determined die junction temperature is then computed as:
TJ = TAMB + PDIS • θJA
where TAMB is ambient temperature and θJA is the package
thermal resistance. For the 20-pin SSOP, θJA is 100°C/W.
Magnetics
Design of magnetics is dependent on topology. The following details the design of the magnetics for a push-pull
converter. In this converter the transformer usually stores
little energy. The following equations should be considered as the starting point to building a prototype.
N=
VOUT + VF
(2 • DC MAX )[VIN(MIN) − ISW (RON + RSENSE)]
DCMAX is the maximum duty cycle of each driver with
respect to the entire cycle, which consists of two periods
(A on and B on). So the effective duty cycle is 2 • DCMAX.
The controller, in general, determines maximum duty
cycle. A 44% maximum duty cycle is a guaranteed value
for this part.
Remember to add sufficient margin in the turns ratio to
account for IR drops in the transformer windings, worstcase diode forward drops and switch on voltage. Also at
very slow slew rates the effective DC may be reduced.
There are a number of ways to choose the inductance
value for L. We suggest as a starting point that L be
selected such that the converter is continuous at
IOUT(MAX)/4. If your minimum IOUT is higher than this or
your components can handle higher peak currents then
use a higher number.
D1
1:N
RON = Switch-on resistance
VOUT
C
ROUT
VIN
LPRI
The following definitions will be used:
VIN = Input supply voltage
L
D2
RSENSE
1683 F07
Figure 7. Push-Pull Topology
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Continuous operation occurs when the current in the
inductor never goes to zero. Discontinuous operation
occurs when the inductor current drops to zero before the
start of the next cycle and can occur with small inductors
and light loads. There is nothing inherently bad about
discontinuous operation, however, converter control and
operation are somewhat different. The inductor is smaller
for discontinuous operation but the peak currents in the
switch, the transformer, the diodes, inductor and capacitor will be higher which may produce greater losses.
For continuous operation the inductor ripple current must
be less than twice the output current. The worst case for
this is at maximum input (lowest duty cycle, DCMIN) but in
the following we will evaluate at nominal input since the
IOUT/4 is somewhat arbitrary.
Note when both inputs are off, the inductor current splits
between both secondary outputs and the diode common
goes to 0V.
Looking at the inductor current during off time, output
ripple current is:
∆IOUT = 2 • IOUT (MIN)
IOUT (MIN) = IOUT (MAX) / 4
L=
(VOUT(MIN) + VF ) • (1− 2 • DC )
∆IOUT • f
The inductance of the transformer primary should be such
that L, when reflected into the primary, dominates the
input current. In other words, we want the magnetizing
current of the transformer small with respect to the
current going through the transformer to L. In general,
then, the inductance of the primary should be at least five
times that of L reflected to the input. This ensures that
most of the power will be passed through the transformer
to the load. It also increases the power capability of the
converter and reduces the peak currents that the switch
will see.
LPRI =
5•L
N2
If the magnetizing current is small, say below 100mA, then
a smaller L can be used with a higher percentage of the
switch current generated by the magnetizing current.
18
With the value of L set, the ripple in the inductor is:
∆IL =
(VOUT + VF ) • (1− 2 • DC )
L• f
However, the peak inductor current is evaluated at maximum load and maximum input voltage (minimum DC).
IL(MAX) = IL(MAX) +
∆IL(MAX)
2
The magnetizing ripple current can be shown to be:
∆IMAG =
VOUT + VF
N • LPRI • f
and the peak current in the switch is:
ISW(PEAK) = N • IL(MAX) + ∆IMAG
This current should be less than the current limit.
Worst-case switch ripple is:
∆ISW(PEAK) = N • ∆IL(MAX) + ∆IMAG
In the push-pull converter the maximum switch voltage
will be 2 • VIN. Because voltage is slew-controlled, the
leakage spikes are small. So, the MOSFET should have a
maximum rated switch voltage at least 20% higher than
2␣ • VIN.
So, given the turns ratio, primary inductance and current,
the transformer can be designed. The design of the transformer will require analyzing the power losses of the
transformer and making necessary adjustments.
Most transformer companies can assist you with designing an optimal solution. For instance Midcom, Inc. (1-800643-2661). Linear Technology’s application group can
also help.
As an example say we are designing a 48V ±20% to 5V
100kHz converter with 2A output and 500mA ripple. Then
starting with a guess for the on voltage of the MOSFET plus
sense resistor of 0.5V and VF of 0.5V:
N=
(
5 + 0.5
)
88%• 48 • 80% − 0.5
=
1
6.1
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For continuous operation at IOUT(MIN) = IOUT(MAX)/4,
inductor ripple (the same as output ripple):
ISW(PEAK) =
2A
∆IL = 2 •
= 1A
4
=
(
VOUT + VF
2 • N VIN(NOM) − ISW • RON
5.5
2
• 47.5
6.1
)
= 35.3%
∆IMAG = N • IL – ∆ISW
The max ripple current on the switch is:
∆ISW(MAX) =
Then
L=
1
• 2.51A + 81mA = 494mA
6.1
Note that you can discern your magnetizing ripple by
looking at the reflected inductance ripple and subtracting
it from the switch current ripple.
The duty cycle for nominal input is:
DC NOM =
Peak switch current is:
(5 + 0.5) • (1− 2 • 35.3%) = 16µH
1A • 100kHz
Off-the-shelf components can be used for this inductor.
Say we choose a 22µH inductor then ripple current at
maximum input (DC = 29.1%) is:
1.03A
+ 81mA = 0.25A
6.1
Knowing the peak switch current we can go back and
iterate with a more accurate switch on voltage. We would
have to know the RON of the FET. In our case our assumptions of a 0.5V switch on voltage is valid for
RON + RSENSE < 1Ω.
Capacitors
The maximum inductor current is:
Correct choice of input and output capacitors is very
important to low noise switcher performance. Push-pull
topologies and other low noise topologies will in general
have continuous currents, which reduce the requirements
for capacitance. However, noise depends more on the ESR
of the capacitors. In addition lower ESR can also improve
efficiency.
1.03A
= 2A +
= 2.52A
2
Input capacitors must also withstand surges that occur
during the switching of some types of loads. Some solid
tantalum capacitors can fail under these surge conditions.
∆IL =
(5 + 0.5) • (1− 2 • 29.1%) = 1.03A
IL(MAX)
22µF • 100kHz
Primary inductance should be greater than:
LPRI = 5 • 22µH • 6.12 = 4.1mH
The secondary inductance would then be:
4.1mH/6.12 = 110µH
The magnetizing ripple current is approximately:
∆IMAG =
5.5
1
• 4.1mH • 100kHz
6.1
= 81mA
Design Note 95 offers more information but the following
is a brief summary of capacitor types and attributes.
Aluminum Electrolytic: Low cost and higher voltage. They
can be used in this application but in general you will need
higher capacitance to achieve low ESR. Additional
nonelectrolytic capacitors may be required to achieve
better performance.
Specialty Polymer Aluminum: Panasonic has come out
with their series CD capacitors. While they are only available for voltages below 16V, they have very low ESR and
good surge capability.
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Solid Tantalum: Small size and low impedance. Typically
the maximum voltage rating is 50V. With large surge
currents the capacitor may need to be derated or you need
a special type such as AVX TPS line.
OS-CON: Lower impedance than aluminum but only available for 35V or less. Form factor may be a problem.
Ceramic: Generally used for high frequency and high
voltage bypass. They may resonate with their ESL before
ESR becomes dominant. Recent multilayer ceramic (MLC)
capacitors provide larger capacitance with low ESR.
There are continuous improvements being made in capacitors so consult with manufacturers as to your specific
needs.
Input Capacitors
The input capacitor should have low ESR at high frequencies since this will be an important factor concerning how
much conducted noise is created.
There are two separate requirements for input capacitors.
The first is for supply to the part’s VIN pin. The VIN pin will
provide current for the part itself and the gate charge
current.
The worst component from an AC point is the gate charge
current. The actual peak current depends on gate capacitance and slew rate, being higher for larger values of each.
The total current can be estimated by gate charge and
frequency of operation. Because of the slewing with this
part gate charge is spread out over a longer time period
than with a normal FET driver. This reduces capacitance
requirements.
Typically the current will have spikes of under 100mA
located at the gate voltage transitions. This is charge/
discharge to and from the threshold voltage. Most slewing
occurs with the gate voltage near threshold.
Since the part’s VIN will typically be under 15V many
options are available for choice of capacitor. Values of
input capacitor for just VIN requirement will typically be in
the 50µF range with an ESR of under 0.1Ω.
In addition to the part supply, decoupling of the supply to
the transformer needs to be considered. If this is the same
supply as the VIN pin then that capacitor will need to be
increased. However, often with this part the transformer
supply will be a higher voltage and as such a separate
capacitor.
The transformer decoupling capacitor will see the switch
current as ripple.
The above switch current computation can be used to
estimate the capacity for these capacitors.
CIN =
1
∆VCAP
− ESR
∆ISW(MAX)
•
DC MIN
f
where ∆VCAP is the allowed sag on the input capacitor.
ESR is the equivalent series resistance for the cap. In
general allowed sag will be a few tenths of volts.
Output Filter Capacitor
The output capacitor is chosen both for capacity and ESR.
The capacity must supply the load current in the switch off
state. While slew control reduces higher frequency components of the ripple current in the capacitor, the capacitor
ESR and the magnitude of the output ripple current
controls the fundamental component. ESR should also be
low to reduce capacitor dissipation.
The capacitance value can be computed by consideration
of desired load ripple, duty cycle and ESR.
C OUT =
1
∆VOUT
− ESR
∆IL(MAX)
•
DC MIN
f
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MOSFET Selection
Setting GCL Voltage
There is a wide variety of MOSFETs to choose from for this
part. The part will work with either normal threshold (3V to
4V) or logic level threshold devices (1V to 2V).
Setting the voltage on the GCL pin depends on what type
of MOSFET is used and the desired gate drive undervoltage lockout voltage.
Select a voltage rating to insure under worst-case conditions that the MOSFET will not break down. Next choose an
RON sufficiently low to meet both the power dissipation
capabilities of the MOSFET package as well as overall
efficiency needs of the converter.
First determine the maximum gate drive that you require.
Typically you will want it to be at least 2V greater than the
maximum threshold. Higher voltages will lower the on
resistance and increase efficiency. Be certain to check the
maximum allowed gate voltage. Often this is 20V but for
some logic threshold MOSFETs it is only 8V to 10V.
The LT1683 can handle a large range of gate charges.
However at very large charge stability may be affected.
The power dissipation in the MOSFET depends on several
factors. The primary element is I2R heating when the
device is on. In addition, power is dissipated when the
device is slewing. An estimate for power dissipation is:

2

2 + ∆I
I

4 +
P = VIN •
ISR



• f + I2 • RON • DC
 2
2 
3 • ∆I2   
VIN − RON •  I2 +

4


  

VSR



where I is the average current, ∆I is the ripple current in the
switch, ISR is the current slew rate, VSR is the voltage slew
rate, f is the oscillator frequency, DC is the duty cycle and
RON is the MOSFET on-resistance.
VGCL needs to be set approximately 0.2V above the desired
max gate threshold. In addition VIN needs to be at least
1.6V above the gate voltage.
The GCL pin can be tied to VIN which will result in a
maximum gate voltage of VIN – 1.6V.
This pin also controls undervoltage lockout of the gate
drives. The undervoltage lockout will prevent the MOSFETs
from switching until there is sufficient drive present.
If GCL is tied to a voltage source or Zener less than 6.8V,
the gate drivers will not turn on until VIN exceeds the GCL
voltage by 0.8V. For VGCL above 6.5V, the gate drives are
insured to be off for VIN < 7.3V and they will be turned on
by VGCL + 0.8V.
If GCL is tied to VIN, the gate drivers are always on
(undervoltage lockout is disabled).
Approximately 50µA of current can be sourced from this
pin if VIN > VGCL + 0.8V. This could be used to bias a Zener.
The GCL pin has an internal 19V Zener to ground that will
provide a failsafe for maximum gate voltage.
As an example say we are using a Siliconix Si4480DY
which has RDS(ON) rated at 6V. To get 6V, VGCL needs to be
set to 6.2V and VIN needs to be at least 7.6V.
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Gate Driver Considerations
In general, the MOSFETs should be positioned as close to
the part as possible to minimize inductance.
When the part is active the gate drives will be pulled low to
less than 0.2V. When the part is off, the gate drives contain
a 40k resistor in series with a diode to ground that will offer
passive holdoff protection. If you are using some logic
level MOSFETs this might not be sufficient. A resistor may
be placed from gate to ground, however the value should
be reasonably high to minimize DC losses and possible AC
issues.
The gate drive source current comes from VIN. The sink
current exits through PGND. In general the decoupling cap
should be placed close to these two pins.
Switching Diodes
In general, switching diodes should be Schottky diodes.
Size and breakdown voltage depend on the specific converter. A lower forward drop will improve converter efficiency. No other special requirements are needed.
PCB Layout Considerations
As with any switcher careful consideration should be given
to PC board layout. Because this part reduces high frequency EMI the board layout is less critical, however high
currents and voltages still produce the need for careful
board layout to eliminate poor and erratic performance.
get coupled into the ground paths of other loops. Using
singular points of connection for the grounds is the best
way to do this. The two major points of connection are the
bottom of the input decoupling cap and the bottom of the
output decoupling cap. Typically the sense resistor device
PGND and device GND will tie to the bottom of the input
cap.
There are two other loops to pay attention to. The current
slew involves a high bandwidth control that goes through
the MOSFET switch, the sense resistor and into the CS pin
of the part and out the GATE pin to the MOSFET. Trace
inductance and resistance should be kept low on the GATE
drive trace. The CS trace should have low inductance. The
sense resistor should be physically close to PGND and the
MOSFETs’ sources.
Finally care should be taken with the CAP A, CAP B pins.
The part will tolerate stray capacitance to ground on these
pins (<5pF) however stray capacitance to the respective
drains should be minimized. This path would provide an
alternate capacitive path for the voltage slew.
More Help
AN70 contains information about low noise switchers and
measurement of noise and should be consulted. AN19 and
AN29 also have general knowledge concerning switching
regulators. Also, our Application Department is always
ready to lend a helping hand.
A
Basic Considerations
Keep the high current loops physically small in area. The
main loops are shown in Figure 8: the power switch loops
(A and B) and the rectifier loop (C and D). These loops can
be kept small by physically keeping the components close
to one another. In addition, connection traces should be
kept wide to lower resistance and inductances. Components should be placed to minimize connecting paths.
Careful attention to ground connections must also be
maintained. Without getting into elaborate detail be careful that currents from different high current loops do not
B
CIN
A
1
3 D
2
4 C
GATE A
COUT
GATE B
CS
1683 F08
Figure 8
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LT1683
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TYPICAL APPLICATIO
Ultralow Noise 48V to ±12V DC/DC Converter
48V
510Ω
0.5W
10k
D1
47µF
100V
CTX0215542
T1
1
FZT853
D2
C4
22µF
50V
D3
C3
10µF
25V
12V
2N3904
8.2V
17
VIN
14
5
976Ω
6
1200pF
7
16.9k
3.3k
25k
3.3k
1k
0.22µF
6
2
D4
10
D5
23.2k
25k
MBR01100
8
16
15
12
3,4
3
GCL
SHDN
CAP A
V5
GATE A
SYNC
CT
CAP B
LT1683
RT
GATE B
RVSL
CS
8,9
D6
5pF
200V
5pF
2
5
D7
7
L1
10µH
12V/1A
C1
33µF
16V, ×2
C2
33µF
16V, ×2
–12V/1A
L2
10µH
1
5pF
200V
5pF
18
25pF
19
4 Si9422
10.0k
2.74k
Si9422
0.068Ω
RCSL
PGND
VC
22nF
SS
13
FB
NFB
GND
11
20
8.66k
9
25pF
1k
10
10nF
C1, C2:SANYO 16TPC33
C3: MURATA GRM235Y5V106Z
C4: NIPPON THCR60EIE226Z
D1, D2, D3 IN4148
D4, D5, D6, D7 MBRS1100
L1, L2: COOPER DS50224
T1: COOPER CTX02-15542
1683 TA03
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PACKAGE DESCRIPTIO
G Package
20-Lead Plastic SSOP (5.3mm)
(Reference LTC DWG # 05-08-1640)
5.20 – 5.38**
(.205 – .212)
1.73 – 1.99
(.068 – .078)
7.07 – 7.33*
(.278 – .289)
20 19 18 17 16 15 14 13 12 11
0° – 8°
.13 – .22
(.005 – .009)
.55 – .95
(.022 – .037)
.65
(.0256)
BSC
NOTE:
1. CONTROLLING DIMENSION: MILLIMETERS
MILLIMETERS
2. DIMENSIONS ARE IN
(INCHES)
7.65 – 7.90
(.301 – .311)
.25 – .38
(.010 – .015)
.05 – .21
(.002 – .008)
G20 SSOP 0501
1 2 3 4 5 6 7 8 9 10
3. DRAWING NOT TO SCALE
*DIMENSIONS DO NOT INCLUDE MOLD FLASH. MOLD FLASH
SHALL NOT EXCEED .152mm (.006") PER SIDE
**DIMENSIONS DO NOT INCLUDE INTERLEAD FLASH. INTERLEAD
FLASH SHALL NOT EXCEED .254mm (.010") PER SIDE
1683f
Information furnished by Linear Technology Corporation is believed to be accurate and reliable.
However, no responsibility is assumed for its use. Linear Technology Corporation makes no representation that the interconnection of its circuits as described herein will not infringe on existing patent rights.
23
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Ultralow Noise 24V to 5V DC/DC Converter
24V
6.9k
COILTRONICS
VP5-1200
OPTIONAL
39µF
MBR2045CT
2N3904
11V
8.2V
68µF
20V
14
5
6
1.5nF
7
16.9k
25k
25k
3.3k
3.3k
1k
15nF
8
16
15
12
SHDN
CAP A
V5
GATE A
SYNC
CT
CAP B
LT1683
RT
GATE B
RVSL
CS
2
10pF
1µH
5V/5A
9
7
6–10
3
11
2–12
3pF
1
17
3
VIN GCL
4.7µH
330µF
4
8
2×330µF
POSCAP
5
MBR2045CT
1
3pF
18
10pF
19
4 IRF540
IRF540
10mΩ
RCSL
PGND
VC
1nF
SS
13
FB
NFB
GND
11
20
7.50k
9
2.49k
10
10nF
1683 TA02
RELATED PARTS
PART NUMBER
DESCRIPTION
COMMENTS
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LT176X Family
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150mA to 3A, SOT-23 to TO-220
LTC1922-1
Synchronous Phase Modulated Full-Bridge Controller
Adaptive DirectSenseTM Zero Voltage Switching, 50W to
Kilowatts, Synchronous Rectification
DirectSense is a trademark of Linear Technology Corporation.
1683f
24
Linear Technology Corporation
LT/TP 0402 2K • PRINTED IN USA
1630 McCarthy Blvd., Milpitas, CA 95035-7417
(408) 432-1900 ● FAX: (408) 434-0507
●
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