TI TPS43000PWRG4

SLUS489 − OCTOBER 2001
FEATURES
APPLICATIONS
D High-Frequency (2-MHz) Voltage Mode PWM
D
D
D
D
D
D
D
D
D
D
D
D
D
D
D
D
D
Controller
1.8-V to 9.0-V Input Voltage Range
0.8-V to 8.0-V Output Voltage Range (Higher in
Non-Synchronous Boost Topology)
High-Efficiency Buck, Boost, SEPIC or
Flyback (Buck-Boost) Topology
Synchronous Rectification for High-Efficiency
Drives External MOSFETs for High-Current
Applications
Synchronizable Fixed-Frequency PWM or
Automatic Pulsed Frequency Modulation
(PFM) Mode
Built-In Soft-Start
User Programmable Discontinuous or
Continuous Conduction Mode
Selectable Pulse-by-Pulse Current Limiting or
Hiccup Mode Protection
TYPICAL BUCK APPLICATION
VIN
TPS43000
5
BUCK
3
RT
1
SYNC/SD PDRV 13
4
CCM
SWP 15
2
CCS
SWN 16
6
PFM*
NDRV 11
12 GND
VOUT 10
7
COMP
Networking Equipment
Servers
Base Stations
Cellular Telephones
Satellite Telephones
GPS Devices
Digital Still and Handheld Cameras
Personal Digital Assistants (PDAs)
DESCRIPTION
The TPS43000 is a high-frequency, voltage-mode,
synchronous PWM controller that can be used in buck,
boost, SEPIC, or flyback topologies. This highly flexible,
full-featured controller is designed to drive a pair of
external MOSFETs (one N-channel and one
P-channel), enabling it for use with a wide range of
output voltages and power levels. With an automatic
PFM mode, a shutdown current of less than 1 µA, a
sleep-mode current of less than 100 µA and a full
operating current of less than 2 mA at 1 MHz, it is ideal
for building highly efficient, dc-to-dc converters.
The TPS43000 operates over a wide input voltage
range of 1.8 V to 9.0 V. Typical power sources are
distributed power systems, two to four nickel or alkaline
batteries, or one to two lithium-ion cells. It can be used
to generate regulated output voltages from as low as
0.8 V to 8 V or higher. It operates either in a
fixed-frequency mode, where the user programs the
frequency (up to 2 MHz), or in an automatic PFM mode.
In the automatic mode, the controller goes to sleep
when the inductor current goes discontinuous, and
wakes up when the output voltage has fallen by 2%. In
this hysteretic mode of operation, very high efficiency
can be maintained over a very wide range of load
current. The device can also be synchronized to an
external clock source using the dual function SYNC/SD
input pin.
VIN 9
VP 14
VOUT
FB 8
RTN
UDG−01036
Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of Texas Instruments
semiconductor products and disclaimers thereto appears at the end of this data sheet.
! " #$%! " &$'(#! )!%*
)$#!" # ! "&%##!" &% !+% !%" %," "!$%!"
"!)) -!.* )$#! &#%""/ )%" ! %#%""(. #($)%
!%"!/ (( &%!%"*
Copyright  2001, Texas Instruments Incorporated
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1
SLUS489 − OCTOBER 2001
description (continued)
The TPS43000 features a selectable two-level current-limit circuit which senses the voltage drop across the
energizing MOSFET. The user can select either pulse-by-pulse current limiting or hiccup mode overcurrent
protection. The TPS43000 also features a low-power (LP) mode (which reduces gate charge losses in the
N-channel MOSFET at high input/output voltages), undervoltage lockout, and soft-start. The TPS43000 is
available in a 16-pin TSSOP (PW) package.
absolute maximum ratings over operating free-air temperature (unless otherwise noted)†w
Input voltage
(VIN, VP, VOUT) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . −0.3 V to 10 V
(BUCK, CCM, CCS, PFM, SYNC/SD) . . . . . . . . . . . . . . . . . . . . . . . −0.3 V to VIN + 0.3 V
(SWN) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . −0.3 V to 17 V
(SWP) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . −0.3 V to VIN + 0.3 V
Storage temperature range, Tstg . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . −65°C to 150°C
Junction temperature range, TJ . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . −55°C to 150°C
Lead temperature 1,6 mm (1/16 inch) from case for 10 seconds . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 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 under “recommended operating conditions” is not
implied. Exposure to absolute- maximum-rated conditions for extended periods may affect device reliability. All voltages are with respect to
ground. Currents are positive into, negative out of the specified terminals.
PW PACKAGE
(TOP VIEW)
SYNC/SD
CCS
RT
CCM
BUCK
PFM
COMP
FB
1
2
3
4
5
6
7
8
16
15
14
13
12
11
10
9
SWN
SWP
VP
PDRV
GND
NDRV
VOUT
VIN
recommended operating conditions
MIN
MAX
Input voltage, VIN, VP
9
Input voltage, VOUT
8
Input voltage, BUCK, CCM, CCS, PFM, SYNC/SD, SWP
9
17
§
Operating junction temperature range, TJ
−40
85
§ t is not recommended that the device operate for extended periods of time under conditions beyond those specified in this table.
UNIT
V
Input voltage, SWN
2
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°C
SLUS489 − OCTOBER 2001
electrical characteristics over recommended operating junction temperature range,
TA = −40_C to 85_C for the TPS43000, RT = 75 kΩ (500 kHz), VIN = VP = 3.5 V, VOUT = 3.1 V, COMP/FB
pins shorted, BUCK-configured, TA = TJ (unless otherwise noted)
VIN
PARAMETER
Start-up voltage
Undervoltage lockout (UVLO) hysteresis
TEST CONDITIONS
VP = VOUT = 3.5 V,
No MOSFETs connected
No load
MIN
TYP
MAX
1.45
1.65
1.85
V
60
150
300
mV
SYNC/SD = 1.6 V
UNIT
1
10
SYNC/SD = VIN
0.5
2
Operating current
Not in PFM mode, no MOSFETs connected
1.0
1.4
mA
Sleep mode current
PFM mode,
75
140
µA
BOOST-configured VIN operating current
Not in PFM mode, no MOSFETs connected,
BUCK pin grounded,
VIN = 3.1 V,
VP = VOUT = 3.5 V
30
75
µA
BOOST-configured VIN sleep mode current
PFM mode, BUCK pin grounded,
VP = VOUT = 3.5 V,
VIN = 3.1 V,
COMP/FB=900 mV
25
60
µA
Shutdown current
COMP/FB=900 mV
µA
A
VOUT
TYP
MAX
Shutdown current
PARAMETER
SYNC/SD = VIN
TEST CONDITIONS
MIN
0
2
Operating current
Not in PFM mode, no MOSFETs connected
1
5
Sleep mode current
PFM mode,
0
2
BOOST-configured VOUT operating current
Not in PFM mode, no MOSFETs connected,
BUCK pin grounded,
VIN = 3.1 V,
VP = VOUT = 3.5 V
1.0
1.4
mA
BOOST-configured VOUT sleep mode current
PFM mode, BUCK pin grounded,
VP = VOUT = 3.5 V,
VIN = 3.1 V,
COMP/FB=900 mV
50
120
µA
TYP
MAX
UNIT
COMP/FB=900 mV
UNIT
µA
VP
PARAMETER
TEST CONDITIONS
MIN
Shutdown current
SYNC/SD = VIN
0.5
2
Operating current
Not in PFM mode, no MOSFETs connected
500
800
Sleep mode current
PFM mode,
0
2
COMP/FB=900 mV
µA
error amplifier
PARAMETER
VREG, regulation voltage (COMP/FB pin)
FB input current
Sourcing current (out of COMP)
Sinking current (into COMP)
Maximum ouput voltage (COMP pin)
Minimum output voltage (COMP pin)
Unity gain bandwidth
MIN
TYP
MAX
1.8 V < VIN < 6 V
TEST CONDITIONS
784
800
816
VIN = 3.5 V
788
800
812
VFB = 800 mV
VFB = (VREG − 100 mV),
VFB = (VREG + 100 mV),
VFB = 0 V,
VFB = 2 V,
See Note 1
−150
VCOMP = 0 V,
VCOMP = 2 V
ICOMP = −100 µA
ICOMP = +100 µA
UNIT
mV
−10
150
nA
−2.0
−0.5
mA
0.5
1.2
mA
1.6
2.0
V
70
5
120
mV
MHz
NOTE 1: Ensured by design. Not production tested.
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3
SLUS489 − OCTOBER 2001
electrical characteristics over recommended operating junction temperature range,
TA = −40_C to 85_C for the TPS43000, RT = 75 kΩ (500 kHz), VIN = VP = 3.5 V, VOUT = 3.1 V, COMP/FB
pins shorted, BUCK-configured, TA = TJ (unless otherwise noted)
soft-start
PARAMETER
Soft-start time
TEST CONDITIONS
MIN
TYP
MAX
RT = 37.5 kΩ (1 MHz)
1.0
3.0
6.0
RT = 75 kΩ (500 kHz)
2.0
5.5
12.0
RT = 150 kΩ (250 kHz)
4.0
10.5
24.0
UNIT
ms
oscillator
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
0.90
1.00
1.10
MHz
RT = 75 kΩ (500 kHz),
VCOMP = 600 mV
VCOMP = 600 mV
450
500
550
kHz
RT = 150 kΩ (250 kHz),
VCOMP = 600 mV
225
250
280
kHz
MIN
TYP
MAX
UNIT
0.8
1.25
1.6
V
1
µA
35
µs
RT = 37.5 kΩ (1 MHz),
Oscillator frequency
SYNC/SD
PARAMETER
TEST CONDITIONS
Synchronization threshold voltage
SYNC pulse width
SYNC/SD = 2 V,
SYNC input current
SYNC/SD = 1.6 V
SYNC high to shutdown delay time
Float COMP,
Synchronous range
Force COMP/FB to 600 mV
COMP/FB=600 mV
100
50
0.5
VFB = 0 V
10
22
1.1 fo
ns
1.5 fo
current limit
PARAMETER
TEST CONDITIONS
Hiccup overcurrent threshold voltage
Voltage measured from VIN to SWN
Delay to termination of P-channel gate drive time
Measured at PDRV
BOOST configured hiccup overcurrent threshold
voltage
Voltage measured from SWN to GND,
BUCK grounded
Delay to termination of N-channel gate drive time
Measured at NDRV,
MIN
TYP
MAX
UNIT
175
250
325
mV
125
300
ns
250
325
mV
150
300
ns
63
75
175
BUCK grounded
Consecutive overcurrent clock cycles before
shutdown
50
Clock cycles before restart
800
900
1000
CCS threshold voltage
0.40
0.70
1.00
V
µA
CCS pull-down current
Constant current source configured if
VCCS > 1 V
0.5
1.0
CCS current threshold voltage
Measured from VIN to SWN
85
150
225
BOOST-configured CCS current threshold voltage
Measured from SWN to GND,
BUCK grounded
85
150
225
4
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mV
SLUS489 − OCTOBER 2001
electrical characteristics over recommended operating junction temperature range,
TA = −40_C to 85_C for the TPS43000, RT = 75 kΩ (500 kHz), VIN = VP = 3.5 V, VOUT = 3.1 V, COMP/FB
pins shorted, BUCK-configured, TA = TJ (unless otherwise noted)
PWM
PARAMETER
TEST CONDITIONS
BUCK threshold voltage
BUCK pull-down current
BUCK maximum duty cycle
MIN
TYP
MAX
0.4
0.7
1.0
V
0.5
1.0
µA
BUCK configured if VBUCK > 1 V
BOOST maximum duty cycle
VFB = 0 V
BUCK grounded,
Minimum duty cycle
VFB = 2 V
UNIT
100%
70%
90%
0.7
1.0
CCM pull-down current
Continuous conduction allowed if
VCCM > 1 V
0.4
0.5
1.0
µA
BUCK rectifier zero current threshold voltage
Measured from SWP to GND
−28
−12
0
mV
BOOST rectifier zero current threshold voltage
Measured from SWP to VOUT,
BUCK grounded
0
14
32
mV
Delay to termination of P-channel gate drive time
Measured at PDRV,
200
300
ns
MIN
TYP
MAX
UNIT
0.4
0.7
1.0
0.5
1.0
µA
768
784
800
mV
5
7
9
2
5
CCM threshold voltage
VFB = 0 V
0%
BUCK grounded
V
pulsed frequency modulation
PARAMETER
TEST CONDITIONS
PFM threshold voltage
PFM pull-down current
PFM mode not allowed if PFM > 1 V
FB voltage to awaken (exit sleep mode)
Izero pulses required to enter sleep
Start-up delay time after sleep
V
µs
low power mode
MIN
TYP
MAX
VOUT threshold voltage to enter low power mode
PARAMETER
VP = VIN = 5 V
3.45
3.60
3.80
VIN threshold voltage to enter low power mode
VP = VOUT = 5 V,
BUCK grounded (boost configured)
3.45
3.60
3.80
VOUT < (VTHRESHOLD−VHYST),
VP = VIN = 5 V
225
312
415
VIN < (VTHRESHOLD−VHYST),
BUCK grounded,
VP = VOUT = 5 V
225
312
415
Hysteresis voltage to exit low power mode
TEST CONDITIONS
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UNIT
V
mV
5
SLUS489 − OCTOBER 2001
electrical characteristics over recommended operating junction temperature range,
TA = −40_C to 85_C for the TPS43000, RT = 75 kΩ (500 kHz), VIN = VP = 3.5 V, VOUT = 3.1 V, COMP/FB
pins shorted, BUCK-configured, TA = TJ (unless otherwise noted)
NDRV
PARAMETER
VIN driven rise time
VIN driven fall time
TEST CONDITIONS
CO = 1 nF,
VOUT = 3.1 V
VP = VIN = 5 V,
VP = VIN = 5 V,
VOUT = 3.1 V
MIN
VIN driven pull-up resistance
VIN driven pull-down resistance
BUCK P-channel MOSFET off to N-channel
MOSFET on anti-x delay time
VP = VIN = 5 V,
VOUT = 3.1 V,
PDRV and NDRV transitioning HI delta
VOUT driven rise time
CO = 1 nF,
VP = VOUT = 5 V,
VIN = 3.1 V,
BUCK grounded
VP = VOUT = VIN = 5 V,
LP mode activated
VP = VOUT = 5 V,
BUCK grounded
VIN = 3.1 V,
VOUT driven fall time
10
VOUT driven pull-up resistance
VOUT driven pull-down resistance
BOOST P-channel MOSFET off to N-channel MOSFET on anti-x delay time
TYP
MAX
25
45
20
40
6.5
10.0
2.25
4.00
35
75
25
45
20
40
6.5
10.0
2.25
4.00
10
35
75
MIN
TYP
MAX
15
40
15
40
2.5
4.0
3.5
6.0
UNIT
ns
Ω
ns
Ω
ns
PDRV
PARAMETER
VP driven rise time
VP driven fall time
TEST CONDITIONS
VP = VIN = 5 V,
CO = 1 nF
VOUT = 3.1 V
VP = VIN = 5 V,
VOUT = 3.1 V
VP driven pull-up resistance
VP driven pull-down resistance
BUCK N-channel MOSFET off to P-channel MOSFET on anti-x delay time
VP = VIN = 5 V,
VOUT = 3.1 V,
NDRV and PDRV transitioning LO delta
10
30
75
BOOST N-channel MOSFET off to P-channel MOSFET on anti-x delay time
VP = VOUT = 5 V,
BUCK grounded
10
30
75
6
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VIN = 3.1 V,
UNIT
ns
Ω
ns
SLUS489 − OCTOBER 2001
Terminal Functions
TERMINAL
NAME
BUCK
CCM
NO.
5
4
DESCRIPTION
I/O
I
Input pin to select topology. Connect this pin to VIN for a buck converter, ground it for a boost or SEPIC.
This configures the logic to the two gate drive outputs, and controls DMAX. This pin has a weak internal
pulldown.
I
Input pin determines whether or not the lZERO comparator allows discontinuous conduction mode operation. Pulling this pin high ignores the Izero comparator’s output, forcing continuous conduction mode.
Connecting it to ground enables Izero, allowing discontinuous conduction mode (DCM) operation. Note
that even when pulled high, seven detected IZERO pulses still initiate PFM mode. This pin has a weak
internal pull-down.
CCS
2
I
Current limit feature allowing selection of either pulse-by-pulse current limiting or hiccup mode overcurrent protection. Connect this pin to VIN to select pulse-by-pulse current limiting, the constant current
source mode. Connect this pin to ground to enable hiccup mode overcurrent protection. This pin has a
weak internal pulldown.
COMP
7
O
Output of the error amplifier. The compensation components are connected from this pin to the FB pin.
During sleep mode, this pin goes to high impedance, and is severed from the internal error amplifier’s
output so that it may hold its dc potential.
FB
8
I
Inverting input to the error amplifier. It is connected to a resistor divider off of VOUT, and to the compensation network.
GND
12
−
Ground pin for the device.
NDRV
11
O
Gate drive output for the N-channel MOSFET (energizing MOSFET for the boost and SEPIC, rectifier
MOSFET for the buck).
PDRV
13
O
Gate drive output for the P-channel MOSFET (energizing MOSFET for the buck, rectifier MOSFET for the
boost and SEPIC).
PFM
6
I
Input pin that disables/enables PFM operation. Connecting it to VIN disables PFM mode. Grounding this
pin enables PFM to occur automatically, based on lzero. This pin has a weak internal pulldown.
RT
3
O
A resistor from this pin to ground sets the PWM frequency.
SWP
15
I
Connect this pin through a 1-kΩ resistor to the drain of the P-channel MOSFET for all topologies. It detects Izero pulses using the synchronous rectifier MOSFET. For the SEPIC topology, a Schottky clamp
tied to ground must be connected to this pin.
SWN
16
I
Connect this pin through a 1-kΩ resistor to the drain of the N-channel MOSFET for all topologies. It
senses overcurrent conditions using the inductor energizing MOSFET.
SYNC/SD
1
I
This dual-function pin is used to synchronize the oscillator or shutdown the controller, turning both
MOSFETs off. A pulse from 0 V to 2 V provides synchronization. Duty cycle is not critical, but it must be
at least 100 ns wide. Holding this pin to 2 V or greater for over 35 µs shuts down the device. This pin
has a weak internal pulldown.
VP
14
I
Power rail input pin for the P-channel MOSFET gate driver. Connect this pin to VIN for a buck, and to
VOUT for a boost or SEPIC. Provide good local decoupling.
VIN
9
I
Input supply for the device. It provides power to the device, and may be used for the N−channel gate
drive. Provide good local decoupling
VOUT
10
O
Connect this pin to the power supply output. It may be used for the gate drive to the N−channel MOSFET. Provide good local decoupling.
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7
SLUS489 − OCTOBER 2001
functional block diagram
+
300 mV
VOUT 10
VINEST
+
R
+
VBEST
800 mV
VREF
1.246 V
VIN 9
2.75 V
784 mV
VDD
UVLO
+
DELAY
TO ZERO
200 mV
1.6 R
VINEST
REFGOOD
REFBAD
3.6 V
+
VIN
VOUT
CCM 4
RECTOFF
(STOP SWITCH
RECTIFICATION)
+
10 mV
GND 12
SWP 15
+
LEB
IZERO
Q
R
Q
LPM
+
VOUT
VIN
3−BIT UP
COUNTER
S
Q
R
Q
SLEEP
LPM
PFM 6
RESET
784 mV
+
VINEST
FB 8
ERROR
AMPLIFIER
+
+
800 mV
REFGOOD
HICCUP
COMP
3.3 V
S
SOFT
START
RECTOFF
SLEEP
S
Q
+
7
R
RT 3
Q
RECTIFY
SHUTDOWN
TIMER AND
OSCILLATOR
SYNC/SD 1
IMAX
PWM
COMPARATOR
95% MAXIMUM DUTY
CYCLE NON−BUCK
ANTI
CROSS
CONDUCTION
&
TOPOLOGY
STEERING
LOGIC
14
VP
13
PDRV
11
NDRV
NDRV_RAIL
SHUTDOWN
(SD)
BUCK 5
CCS 2
PWM ENABLE
+
150 mV
RESET
RESET
+
+
250 mV
SWN 16
LEB
6−BIT
UP/DOWN
COUNTER
SHUTDOWN
FOR 900
CYCLES THEN
SOFT−START
SD
REFBAD
SLEEP
HICCUP
HICCUP
(STOP SWITCHING FOR 900
CYCLES THEN SOFT−START)
IMAX
(STOP ENERGIZING INDICATOR)
TPS43000
UDG−01043
8
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SLUS489 − OCTOBER 2001
APPLICATION INFORMATION
general information
The TPS43000 is a high-frequency, synchronous PWM controller optimized for distributed power, or
battery-powered applications where size and efficiency are of critical importance. It includes high-speed,
high-current MOSFET drivers for those applications requiring low RDS(on) external MOSFETs. (See functional
block diagram).
optimizing efficiency
The TPS43000 optimizes efficiency and extends battery life with its low quiescent current and its synchronous
rectifier topology. The additional features of low-power (LP) mode and PFM mode maintain high efficiency over
a wide range of load current.
modes of operation
The TPS43000 has four distinct modes of operation:
D
D
D
D
fixed PWM with discontinuous conduction mode (DCM) possible
fixed PWM with forced continuous conduction mode (CCM)
automatic pulse frequency modulation (PFM) with DCM possible
PFM with forced CCM
The device mode is controlled by the CCM and PFM pins. The CCM pin lets the user decide whether to allow
DCM by connecting the pin to ground or to force CCM by connecting the pin to VIN. The PFM pin lets the user
decide whether to allow automatic PFM by connecting the pin to ground or to force fixed PWM by connecting
the pin to VIN.
fixed PWM with DCM possible (PFM tied to VIN; CCM tied to ground)
In this mode, the device behaves like a standard switching regulator with the addition of a synchronous rectifier.
Shortly after the energizing MOSFET turns off, the synchronous rectifier turns on. The synchronous rectifier
turns off either when the inductor current goes discontinuous (DCM) or just prior to the start of the next clock
cycle (CCM) when the energizing MOSFET turns on. During the small time interval when neither the energizing
MOSFET nor the synchronous rectifier are turned on, the synchronous rectifier MOSFET body diode (or an
optional small external Schottky diode in parallel) carries the current to the output until it goes discontinuous.
The efficiency drops off at light loads as the losses become a larger percentage of the delivered load.
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9
SLUS489 − OCTOBER 2001
APPLICATION INFORMATION
fixed PWM with forced CCM (PFM and CCM tied to VIN)
CCM is forced under all operating conditions in this mode. The synchronous rectifier turns on shortly after the
energizing MOSFET turns off and remains on until just prior to the start of the next clock cycle when the
energizing MOSFET turns on. The user should design the converter to operate in CCM over its entire operating
range in order to prevent the inductor current from going negative. If the converter is allowed to run
discontinuous, the inductor current goes negative (i.e. the output discharges as the current reverses and goes
back through the rectifier to the input or ground.) With fixed PWM, the efficiency drops off at light loads as the
losses become a larger percentage of the delivered load.
PFM with DCM possible (PFM and CCM tied to ground)
In this mode, the device can operate in either fixed PWM or in PFM mode. When the device is initially powered,
it operates in fixed PWM mode until soft-start completion. It remains in this mode until it senses that the converter
is on the verge of breaking into discontinuous operation. When this condition is sensed, the converter enters
PFM mode, invoking a sleep state until the output voltage falls 2% below nominal (a 16-mV drop measured at
the FB pin). At this time, the controller starts up again and operates at its fixed PWM frequency for a short
duration (load dependent, typically 10 to 200 PWM cycles), increasing the output voltage. If the controller again
senses the converter is on the verge of going discontinuous, the cycle repeats. If discontinuous operation is not
sensed, the converter remains in fixed PWM mode. PFM mode results in a very low duty cycle of operation,
reducing all losses and greatly improving light load efficiency. During the sleep state, most of the circuitry internal
to the TPS43000 is powered down. This reduces quiescent current, which lowers the average dc operating
current, enhancing its efficiency.
PFM with forced CCM (PFM tied to ground; CCM tied to VIN)
This mode is similar to the PFM with DCM possible mode except that the controller forces the converter to
operate in CCM. The converter can be designed to run discontinuous at light loads. The controller senses
discontinuous operation and enters the PFM mode. With PFM, the converter can maintain a very high efficiency
over a very wide range of load current.
anticross−conduction and adaptive synchronous rectifier commutation logic
When operating in the continuous conduction mode (CCM), the energizing MOSFET and the synchronous
rectifier MOSFET are simply driven out of phase, so that when one is on the other is off. There is a built-in time
delay of about 40 ns to prevent any cross-conduction.
In the event that the converter is operating in the discontinuous conduction mode (DCM), the synchronous
rectifier needs to be turned off quickly, when the rectifier current drops to zero. Otherwise, the output begins to
discharge as the current reverses and goes back through the rectifier to the input or ground (this obviously
cannot happen when using a conventional diode rectifier). To prevent this, the TPS43000 incorporates a
high-speed comparator that senses the voltage on the synchronous rectifier using the SWP input, which is
connected to the synchronous rectifier MOSFET’s drain through a 1-kΩ resistor. This comparator is used to
determine when the inductor current is on the verge of going discontinuous and is referred to as the IZERO
comparator. In the boost and SEPIC (single-ended primary inductance converter) topologies, the synchronous
rectifier is turned off when the voltage on the SWP pin decreases to within 12 mV of VOUT. For this reason, it
is important to have the VOUT pin well decoupled. In the buck topology, the synchronous rectifier is turned off
when the voltage on the SWP pin increases to −12 mV with respect to ground. The IZERO threshold is defined
as follows:
l
10
ZERO
+ 12 mV
R
DS(on)
(1)
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SLUS489 − OCTOBER 2001
APPLICATION INFORMATION
When the RDS(on) of the MOSFET is used as the sense element, several issues arise. Before the IZERO
comparator is enabled, the MOSFET must be fully enhanced, and the drain-to-source voltage must be allowed
to settle. The TPS43000 has an internal circuit that enables the IZERO comparator approximately 40 ns after
the rectifier MOSFET is enhanced.
NOTE: For the SEPIC topology, the voltage on the drain of the rectifier MOSFET swings to −VIN
when the energizing MOSFET is on. Therefore, in order to prevent the SWP input pin from being
damaged, it must connect to a Schottky diode clamp to ground.
PFM mode
For improved efficiency at light loads, the TPS43000 can be programmed to automatically enter PFM (Pulse
Frequency Modulation) mode by connecting the PFM pin to ground. PFM is initiated by the IZERO comparator
used for synchronous rectifier commutation. An internal digital counter is used to count the number of IZERO
pulses at the output of the IZERO comparator. When seven IZERO pulses occur, the controller enters sleep state
until the voltage at the FB pin falls to approximately 784 mV (output voltage drops 2% below nominal). At this
time, the controller turns back on and operates at its fixed-frequency for a short duration (load dependent,
typically 10 to 200 PWM cycles) increasing the output voltage. The cycle repeats when another seven IZERO
pulses occur. This results in a very low duty cycle of operation, reducing all losses and improving light load
efficiency. During the sleep state, most of the circuitry internal to the TPS43000 is powered down. This reduces
quiescent current, which lowers the average dc operating current, enhancing its efficiency. The error amplifier
output is disconnected from the COMP pin during the sleep state. The COMP pin goes to high impedance and
maintains approximately the same voltage level it was at when it entered the sleep state. This minimizes error
amplifier overshoot/undershoot when coming out of the sleep state. The user can disable PFM by connecting
the PFM pin to VIN.
low power mode
At relatively high gate drive voltages, gate drive losses can become excessive and begin to dominate under light
load conditions. The expression for gate drive power loss is given by equation (2). The power varies as a function
of the applied gate voltage squared.
P
GATELOSS
+
Q
G
ǒVGǓ
V
2
f
,
S
(2)
where QG is the total gate charge, VS is the gate voltage specified in the MOSFET manufacturer’s data sheet,
VG is the applied gate drive voltage, and f is the switching frequency.
When both VIN and VOUT are above 3.6 V, the TPS43000 automatically enters LP mode and selects the lower
voltage of VIN or VOUT to provide the gate drive voltage on the NDRV pin. This minimizes gate drive losses
at relatively high input and output voltages and helps maintain high efficiency at light loads. The PDRV pin
remains powered by either VIN (buck topology) or VOUT (boost, flyback, and SEPIC topologies) via the VP
power input pin.
To help provide a smooth transition in and out of LP mode, its circuitry has 300 mV of hysteresis. When either
VIN or VOUT drops below 3.3 V, the TPS43000 transitions back to normal mode and the NDRV pin is powered
by the higher potential of VIN or VOUT.
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11
SLUS489 − OCTOBER 2001
APPLICATION INFORMATION
synchronization and shutdown
The TPS43000 incorporates a dual function synchronization and shutdown pin. It may be used to synchronize
the TPS43000’s switching frequency to an external clock, or to shutdown the device entirely.
To synchronize the internal clock to an external source, the SYNC/SD pin must be driven high, greater than
1.6 V. The circuitry synchronizes to the rising edge of the input. Duty cycle is not critical, but the pulse width must
be at least 100 ns wide but less than 10 µs to avoid shutdown. The external SYNC clock should be between
10% and 25% above the free-running switching frequency.
To ensure a shutdown of the converter, the SYNC/SD pin must be held high (above 1.6 V) for a minimum of
35 µs. In shutdown, both the energizing and rectifier MOSFETs are turned off. The quiescent current is reduced
to less than 10 µA with 1.6 V applied to SYNC/SD and less than 2 µA with VIN potential applied to SYNC/SD.
Bringing this pin low again allows the device to resume operation, starting with a full soft-start cycle.
overcurrent protection
The TPS43000 allows the user to select either pulse-by-pulse current limiting or hiccup mode overcurrent
protection using the CCS pin. To minimize external part count and minimize losses, the energizing MOSFET’s
RDS(on) is used as the current sense element. The TPS43000 incorporates a high-speed comparator, referred
to as the IMAX comparator, that senses the voltage across the energizing MOSFET using the SWN input ,which
is connected to the energizing MOSFET’s drain through a 1-kΩ resistor. The IMAX comparator compares its
SWN input to either ground (boost, flyback, and SEPIC topologies) or VIN (buck topology). Before the IMAX
comparator is enabled, the energizing MOSFET must be fully enhanced, and the drain-to-source voltage must
be allowed to settle. The TPS43000 has an internal circuit that enables the IMAX comparator approximately
60 ns after the energizing MOSFET is enhanced.
pulse-by-pulse current limiting − constant current source mode (CCS tied to VIN)
In the pulse-by-pulse current limiting mode, the energizing MOSFET gate drive is terminated once the
overcurrent threshold is reached. An overcurrent, IMAX, is sensed when the voltage drop across the energizing
MOSFET reaches 150 mV. The pulse-by-pulse current limiting threshold is defined by the equation:
I
MAX(pp)
+ 150 mV
R
DS(on)
(3)
In the boost, flyback, and SEPIC topologies, IMAX(pp) is reached when the voltage on the SWN pin is 150 mV
above ground. In the buck topology, IMAX(pp) is reached when the voltage on the SWN pin is 150 mV below
VIN. For this reason, it is important to have the VIN pin well decoupled. Pulse-by-pulse current limiting is enabled
by connecting the CCS input pin to VIN.
hiccup mode over current protection (CCS tied to ground)
In the hiccup mode overcurrent protection scheme, an internal digital counter is used to count the number of
IMAX pulses at the output of the IMAX comparator. An IMAX condition is sensed when the voltage drop across
the energizing MOSFET reaches 250 mV. The hiccup mode overcurrent threshold is defined by the equation:
I
MAX(hu)
+ 250 mV
R
DS(on)
(4)
In the boost, flyback, and SEPIC topologies, IMAX(hu) condition is reached when the voltage on the SWN pin is
250 mV above ground. In the buck topology, IMAX(hu) condition is reached when the voltage on the SWN pin
is 250 mV below VIN. When 63 IMAX(hu) pulses are reached, both the energizing MOSFET and rectifier MOSFET
are turned off. The MOSFET switches are held off for 882 clock cycles before a soft-start is initiated. Hiccup
mode overcurrent protection is enabled by connecting the CCS input pin to ground.
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SLUS489 − OCTOBER 2001
APPLICATION INFORMATION
start-up and soft-start
The TPS43000 incorporates an UVLO circuit that disables the output drivers when the voltage at the VIN pin
is below 1.65 V. In order to prevent the converter from oscillating during low input voltage startup, the UVLO
circuit is designed with 200 mV of hysteresis and the converter remains on until VIN drops below 1.45 V.
The TPS43000 has a built-in soft-start that varies as a function of the switching frequency. The soft-start is a
closed-loop soft-start, meaning that the reference input to the error amplifier is ramped up over the soft-start
interval and the converter control loop is allowed to track the ramping reference signal. The soft-start interval
is set to approximately 2000 oscillator clock cycles. This method generally allows for faster soft-start times with
minimal output voltage overshoot at startup. During start-up, the synchronous rectifier is held off until the COMP
pin reaches 700 mV.
programming the PWM frequency
The oscillator frequency is programmed by a resistor from the RT pin to ground. The approximate operating
frequency is determined by the equation:
f
SW
(MHz) +
38
R (kW)
T
(5)
The maximum operating frequency is 2 MHz. Some applications may want to remain in a fixed-frequency mode
of operation, even at light load, rather than going into PFM mode. This lowers efficiency at light load. One way
to improve the efficiency while maintaining fixed frequency operation is to lower the PWM frequency under
light-load conditions. This can be easily done, as shown in Figure 1. By adding a second timing resistor and a
small MOSFET switch, the host can switch between two discrete frequencies at any time.
TPS43000
1
SYNC/SD
SWN 16
2
CCS
SWP 15
3
RT
4
CCM
PDRV 13
5
BUCK
GND 12
6
PFM
NDRV 11
7
COMP
VOUT 10
8
FB
RT2
RT1
FREQUENCY
CONTROL
2N7002
VP 14
R1
VOUT
VIN
9
R2
UDG−01035
Figure 1. Changing the PWM Frequency
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SLUS489 − OCTOBER 2001
APPLICATION INFORMATION
error amplifier
The TPS43000 uses voltage mode control for each of the topologies. The output voltage is sensed and fed back
to the FB pin (inverting input) and compared to an internal 800 mV reference connected to the non-inverting
input. The difference (i.e. error voltage), is amplified by the internal error amplifier. The output of the error
amplifier (COMP), is then compared to the oscillator sawtooth ramp to control the pulse width used to drive the
power switch (energizing MOSFET). The duty cycle is varied to regulate the output voltage. The higher the error
voltage, the longer the energizing MOSFET switch is on.
The transient response of a converter is a function of both small signal and large signal responses. The small
signal response is determined by the error amplifier’s loop compensation (feedback network), whereas the large
signal response is a function of the error amplifier’s gain bandwidth and slew rate (dv/dt) as well as the slew
rate of the inductor current (di/dt). The TPS43000 internal error amplifier has a 5-MHz unity gain bandwidth. This
almost assures that the loop bandwidth is limited by external circuit characteristics rather than error amplifier
limitations. The internal error amplifier is capable of sourcing and sinking an ensured 500 µA, which assures
that even during large signal transients, external components determine circuit behavior. Using low feedback
capacitance allows the error amplifier to rapidly slew from one level to another, insuring excellent transient
response.
loop compensation
The voltage loop needs to be compensated to provide control loop stability margin, and to minimize the output
voltage overshoot/undershoot response to line and load transients. A Type III error amplifier compensation
network can be used to optimize the loop response for any of the topologies and operating modes implemented
with the TPS43000. The Type III amplifier circuit is shown in Figure 2. This configuration has a pole at the origin
and two zero-pole pairs. It can provide up to 180° of phase boost.
Av1
R3
C3
R2
C1
R1
Gain − dB
C2
0 dB
VOUT
RBIAS
+
Av2
VREF
fz1
Figure 2. Type III Error Amplifier Compensation
Network
14
fz2
fp1
t − Time − ns
fp2
Figure 3. Type III Error Amplifier Compensation
Gain Response
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SLUS489 − OCTOBER 2001
APPLICATION INFORMATION
The frequency of the poles and zeros are defined by the following equations:
zeros
f z1 +
(2p
1
R2
C1)
f z2 [
(2p
1
R1
C3)
f p1 +
(2p
1
R3
C3)
f p2 [
(2p
1
R2
C2)
(6)
, assuming R1 ơ R3
(7)
poles
(8)
, assuming C1 ơ C2
(9)
In voltage mode control, the buck, boost, flyback, and SEPIC toplogies all have a 2nd order double-pole LC filter
characteristic when operated in CCM. In the buck topology, the frequency of the LC double pole is straight
forward.
f
LC
+
1
buck topology
ǒ2p(LC)1ń2Ǔ
(10)
In the boost, flyback, and SEPIC toplogies, the frequency of the LC double pole varies as a function of the duty
cycle.
f
LC
+
(1 * D)
boost, flyback, & SEPIC topologies
ǒ2p(LC)1ń2Ǔ
(11)
In addition, each of the topologies have an ESR zero, which occurs when the output capacitor impedance
transitions from capacitive to resistive. The frequency at which this occurs is the ESR zero frequency, fESR, and
is defined by the equation:
f
ESR
+
ǒ
1
2p R
Ǔ
ESR
C
(12)
In the boost, flyback, and SEPIC topologies operated in CCM, there is also a right half-plane (RHP) zero. The
RHP zero has the same positive gain slope as the conventional zero, but has a 90° phase lag. This combination,
in conjunction with its dependence on line and load, make it nearly impossible to compensate within the control
loop. The frequency at which this RHP zero occurs, fRHP, is defined by the equations:
f
f
RHP
RHP
+
+
R
R
O
O
(1 * D)
2
boost topology
(2 p L)
(1 * D)
(2 p LD)
(13)
2
flyback topology
(14)
where RO is the equivalent output load resistance.
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SLUS489 − OCTOBER 2001
APPLICATION INFORMATION
With voltage-mode control, the closed-loop design goal for each of the topologies with the Type III error amplifier
compensation is to set the crossover frequency above the resonant frequency of the LC filter (prevents filter
oscillations during a transient response), but below the lowest possible RHP zero frequency. This is
accomplished by setting the two zeros in the compensation network before the LC double pole frequency. This
provides a phase boost. The two poles should be placed a decade above the crossover frequency.
The following is a typical procedure for selecting the loop compensation values for a buck converter operated
in CCM:
Step 1. Select the desired crossover frequency a decade above the LC pole frequency.
Step 2. Set the resistor divider formed by R1 and RBIAS to develop the desired regulation voltage. Note that
RBIAS sets the dc operating point of the loop, but has no effect on ac operation and does not factor into
the loop compensation calculations.
Step 3. Set the zero formed by R1 and C3 to approximately one-half decade above the LC double pole to
compensate for the phase loss.
Step 4. Set the zero formed by R2 and C1 to approximately one-half decade below the LC double pole to avoid
a conditional instability.
Step 5. Set the pole formed by R3 and C3 to cancel the ESR zero of the output capacitor.
Step 6. Set the pole formed by R2 and C2 to approximately one-half decade above the crossover frequency.
If the converter is operated in DCM, the lead network (R3 and C3 in Figure 2) can be eliminated for all topologies.
This configuration is referred to as a Type II error amplifier compensation network and has a pole at the origin
and a single zero-pole pair. It can provide up to 90° of phase boost. The frequency of the pole and zero are
defined by the following equations:
zero
f z1 +
(2p
1
R2
C1)
f p1 [
(2p
1
R2
C2)
(15)
pole
, Assuming C1 ơ C2
(16)
The zero-pole pair is used to compensate for the power circuit’s ESR zero and the pole formed by the output
capacitor and the effective output resistance.
16
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SLUS489 − OCTOBER 2001
APPLICATION INFORMATION
design examples: buck, boost, non-synchronous boost, flyback, and SEPIC
buck converter
The buck topology is simple and efficient, and should be used whenever the desired output voltage is less than
the minimum input voltage. Figure 4 shows the TPS43000 in a typical (750 kHz) buck converter with an input
voltage range of 3.0 V to 9.0 V, an output voltage of 2.7 V, and a load current from 0 A to 2 A.
L1
3.3 µH
Q2
Si9803DY
VOUT
VIN
C7
100 µF
C8
120 µF
R5
1 kΩ
TPS43000
1
SYNC/SD SWN 16
2
CCS
3
RT
4
CCM
PDRV 13
5
BUCK
GND 12
6
PFM
NDRV 11
7
COMP
VOUT 10
8
FB
SWP 15
R4
49.9 kΩ
C2
10 pF
C1
560 pF
R2
75 kΩ
VP 14
VIN
C3
100 pF
VIN
C6
0.47 µF
D1
ZHCS1000
(OPTIONAL)
9
R3
49.9 kΩ
Q1
Si9804DY
VIN
C5
0.47 µF
C4
0.47 µF
R1
127 kΩ
RBIAS
53.6 kΩ
UDG−01035
Figure 4. 2.7-V Output Buck Topology
For a buck converter, the average output current is related to the peak inductor current by:
I
pk
+I
OUT
)
ǒVIN * VOUTǓ D
ǒ2 fSW LǓ
(17)
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17
SLUS489 − OCTOBER 2001
APPLICATION INFORMATION
where fSW is the switching frequency, L is the inductor value, and D is the duty cycle. The duty cycle for a buck
converter is defined as:
V
D + OUT
V
IN
(18)
Note that in these equations the voltage drop across the rectifier has been neglected.
boost converter
The boost topology is simple and efficient, and should be used whenever the desired output voltage is greater
than the maximum input voltage. Figure 5 shows the TPS43000 in a typical (750 kHz) boost converter with an
input voltage range of 2.5 V to 4.5 V, an output voltage of 5.0 V, and a load current from 0 A to 1 A.
D1
L1
3.3 µH
ZHCS1000
(OPTIONAL)
VIN
C7
100 µF
Q2
Si9803DY
R5
1 kΩ
TPS43000
1
SYNC/SD
SWN 16
2
CCS
SWP 15
3
RT
4
CCM
PDRV 13
5
BUCK
GND 12
6
PFM
NDRV 11
7
COMP
VOUT 10
8
FB
R4
49.9 kΩ
C2
330 pF
C1
3300 pF
R2
30.1 kΩ
VOUT
C8
120 µF
VP 14
C6
0.47 µF
VIN
C3
680 pF
Q2
Si9804DY
9
R3
24.9 kΩ
VIN
C5
0.47 µF
C4
0.47 µF
R1
280 kΩ
RBIAS
53.6 kΩ
UDG−01037
Figure 5. 5-V Output Boost Topology
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SLUS489 − OCTOBER 2001
APPLICATION INFORMATION
For a boost converter, the average output current is related to the peak inductor current by the following
equation:
I
pk
+
ǒVOUT
ǒh
I
V
OUT
Ǔ
Ǔ
)
IN
ǒ2
ǒVIN
f
SW
D
Ǔ
Ǔ
L
(19)
where fSW is the switching frequency, L is the inductor value, and D is the duty cycle. The duty cycle for a boost
converter is defined as:
D+
ǒVOUT * VINǓ
V
OUT
(20)
Note that in these equations the voltage drop across the rectifier has been neglected.
non−synchronous boost converter
The TPS43000 can also be used in non-synchronous applications to provide output voltages greater than 8 V
from low voltage inputs. Figure 6 shows the TPS43000 in a non-synchronous boost converter (750 kHz)
application with an input voltage range of 2.5 V to 9.0 V, an output voltage of 12 V, and a load current from 0
A to 1 A. Since none of the device pins are exposed to the boosted voltage, the output voltage is limited only
by the ratings of the external MOSFET, rectifier, and filter capacitor. At these higher output voltages, good
efficiency is maintained since the rectifier drop is small compared to the output voltage. Note that the PFM mode
can still be used to maintain high efficiency at light load.
Since all the power supply pins (VIN, VOUT, VP) operate off the input voltage, it must be greater than 2.5 V and
high enough to assure proper gate drive to the charge MOSFET.
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SLUS489 − OCTOBER 2001
APPLICATION INFORMATION
L1
3.3 µH
D1
ZHCS1000
VIN
VOUT
C7
100 µF
C8
120 µF
R5
1 kΩ
TPS43000
1
SYNC/SD
SWN 16
2
CCS
SWP 15
3
RT
4
CCM
5
BUCK
6
PFM
NDRV 11
7
COMP
VOUT 10
8
FB
R4
49.9 kΩ
C2
330 pF
C1
3300 pF
R2
30.1 kΩ
VP 14
PDRV 13
GND 12
VIN
C3
680 pF
VIN
C6
0.47 µF
9
R3
24.9 kΩ
Q2
Si9804DY
VIN
VIN
C5
0.47 µF
C4
0.47 µF
R1
750 kΩ
RBIAS
53.6 kΩ
UDG−01038
Figure 6. 12-V Output Non-Synchronous Boost Topology
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SLUS489 − OCTOBER 2001
APPLICATION INFORMATION
flyback converter
A flyback converter (750 kHz) using the TPS43000 is shown in Figure 7. It uses a standard two-winding coupled
inductor with a 1:1 turns ratio. The advantage of this topology is that the output voltage can be greater or less
than the input voltage. For example, this is ideal for generating 3.3 V from a lithium-ion cell.
D1
L1B
ZHCS1000
(OPTIONAL)
VIN
L1A
3.3 µH
C7
100 µF
Q2
Si9803DY
TPS43000
1
SYNC/SD
2
CCS
3
RT
4
CCM
5
BUCK
C2
82 pF
R2
24.9 kΩ
C8
120 µF
R5 1 kΩ
SWN 16
R6 1 kΩ
SWP 15
R4
49.9 kΩ
C1
3900 pF
VOUT
VP 14
PDRV
C6
0.47 µF
13
GND 12
6
PFM
NDRV 11
7
COMP
VOUT 10
8
FB
VIN
C3
1200 pF
R3
6.81 kΩ
Q1
Si9804DY
VIN
9
C5
0.47 µF
C4
0.47 µF
R1
169 kΩ
RBIAS
53.6 kΩ
UDG−01039
Figure 7. 3.3-V Output Flyback Topology
NOTE: Resistor-capacitor snubbers can be placed across the primary and secondary windings to
reduce ringing due to leakage inductance. These are optional, and may not be required in the
application.
For a flyback converter, the average output current is related to the peak inductor current by:
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21
SLUS489 − OCTOBER 2001
I
pk
+
ǒVOUT
ǒh
I
V
OUT
Ǔ
Ǔ
IN
)
ǒ2
ǒVIN
f
D
Ǔ
SW
Ǔ
L
(21)
where fSW is the switching frequency, L is the inductor value, and D is the duty cycle. The duty cycle for a flyback
converter is defined as:
D+
V
OUT
ǒVIN ) VOUTǓ
(22)
Note that in these equations the voltage drop across the rectifier has been neglected.
SEPIC converter
The TPS43000 may also be used in the SEPIC topology. This topology, which is similar to the flyback, uses a
capacitor to aid in energy transfer from input to output. Figure 8 shows the TPS43000 in a SEPIC converter
(750 kHz) application with an input voltage range of 2.5 V to 6.0 V, an output voltage of 3.3 V, and a load current
from 0 A to 1 A.
D1
L1B
C9
10 µF
VIN
L1A
4.9 µH
C7
100 µF
ZHCS1000
(OPTIONAL)
Q2
Si9803DY
TPS43000
VOUT
C8
120 µF
R5 1 kΩ
1
SYNC/SD SWN 16
2
CCS
R6 1 kΩ
SWP 15
R4
49.9 kΩ
D1 BAT54
3
C2
82 pF
C1
3900 pF
R2
24.9 kΩ
VP 14
RT
C6
0.47 µF
PDRV 13
4
CCM
5
BUCK
6
PFM
NDRV 11
7
COMP
VOUT 10
8
FB
GND 12
Q1
Si9804DY
VIN 9
C3
1200 pF
R3
6.81 kΩ
C5
0.47 µF
C4
0.47 µF
R1
169 kΩ
RBIAS
53.6 kΩ
UDG−01040
Figure 8. 3.3-V Output SEPIC Topology
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SLUS489 − OCTOBER 2001
APPLICATION INFORMATION
The SEPIC topology offers the same advantage of the flyback in that it can generate an output voltage that is
greater or less than the input voltage. However, it also offers improved efficiency. Although it requires an
additional capacitor in the power stage, it greatly reduces ripple current in the input capacitor and improves
efficiency by transferring the energy in the leakage inductance of the coupled inductor to the output. This also
provides snubbing for the primary and secondary windings, eliminating the need for RC snubbers. Note that
the capacitor must have low ESR, with sufficient ripple current rating for the application. Another advantage of
the SEPIC is that the inductors do not have to be on the same core.
theory of operation
When the energizing MOSFET (Q1) is on, VIN is applied across L1A with the dotted end negative (see Figure 8).
At the same time, the voltage across the SEPIC capacitor C9 (equal to VIN) is applied across L1B with its dotted
end also negative. Since L1A = L1B and the voltages across the two inductors are equal (VIN), the inductor
currents ramp up at the same rate (di/dt=VIN/L). The energizing MOSFET current is the sum of the two inductor
currents. When the energizing MOSFET turns off, the inductor current wants to continue to flow causing the
inductor voltages to reverse until the output rectifer begins to conduct. The voltage across L1B is clamped to
VOUT (plus the rectifier drop) and with its dotted end positive. The voltage across the SEPIC capacitor (VIN)
cancels with VIN and the voltage across L1A is also VOUT with its dotted end positive. Again, since L1A=L1B
and the voltage across the two inductors are equal (VOUT), the inductor current ramps down at the same rate
(di/dt=VOUT/L). The SEPIC capacitor is charged by L1A when the energizing MOSFET is off and is discharged
by L1B when the energizing MOSFET is on. Since the voltages across the inductors are identical at all times
throughout the switcing cycle, the inductors can be coupled on a single magnetic core with an equal number
of turns. This improves the SEPIC application’s dynamic performance and also allows reduction of the input
filtering requirements through ripple steering.
selecting the inductor
The inductor must be chosen based on the desired operating frequency and the maximum load current. Higher
frequencies allow the use of lower inductor values, reducing component size. Higher load currents require larger
inductors with higher current ratings and less winding resistance to minimize losses. The inductor must be rated
for operation at the highest anticipated peak current. Refer to equations 17, 19, and 21 to calculate the peak
inductor current for a buck, boost, flyback, or SEPIC design, based on VIN, VOUT, duty cycle, maximum load,
frequency, and inductor value. Some manufacturers rate their parts for maximum energy storage in microjoules
(µJ). This is expressed by:
E + 0.5
L
ǒIpkǓ
2
(23)
where E is the required energy rating in microjoules, L is the inductor value in microhenries (µH) (with current
applied), and Ipk is the peak current in amps that the inductor sees in the application. Another way in which
inductor ratings are sometimes specified is the maximum volt-seconds applied. This is given simply by:
ET +
ǒVIN
f
Ǔ
D
SW
(24)
where ET is the required rating in V-µs, D is the duty cycle for a given VIN and VOUT, and fSW is the switching
frequency in MHz. Refer to equations 18, 20, and 22 to calculate the duty cycle for a buck, boost, flyback, or
SEPIC converter.
In any case, the inductor must use a low loss core designed for high-frequency operation. High-frequency ferrite
cores are recommended. Some manufacturers of off-the-shelf surface-mount designs are listed in Table 1. For
flyback and SEPIC topologies, use a two-winding coupled inductor. SEPIC designs can also use two discrete
inductors.
www.ti.com
23
SLUS489 − OCTOBER 2001
APPLICATION INFORMATION
Table 1. SMT Commercial Inductor Manufacturers
Coilcraft Inc.
(800) 322−2645
1102 Silver Lake RD, Cary, IL 60013
Coiltronics Inc.
(407) 241−7876
6000 Park of Commerce Blvd, Boca Raton, FL 33487
Dale Electronics, Inc.
(605) 665−9301
East Highway 50, Yankton, SD 57078
Pulse Engineering Ltd.
(204) 633−432
1300 Keewatin Street, Winnipeg, MB R2X 2R9
1−847−545−6700
Fax 1−847−545−6720
Sumida
1701 Golf Road, Tower 3, Suite 400,
Rolling Meadows, IL 60008
BH Electronics
(612) 894−9590
12219 Wood Lake Drive, Burnsville, MN 55337
Tokin America Inc.
(408) 432−8020
155 Nicholson Lane, San Jose CA 95134
selecting the filter capacitor
The input and output filter capacitors must have low ESR and low ESL. Surface-mount tantalum, OSCONs or
multilayer ceramics (MLCs) are recommended. The capacitor selected must have the proper ripple current
rating for the application. Some recommended capacitor types are listed in Table 2.
Table 2. Recommended SMT Filter Capacitors
Manufacturer
Part Number
Features
AVX
TPS series
Low ESR tantalum
Kemet
T410 series
Low ESR tantalum
Murata
GRM series
Low ESR ceramic
Sanyo
OSCON series
Low ESR organic
591D series
Low ESR, low profile tantalum
594D series
Low ESR tantalum
Tokin
Y5U, Y5V Type
Low ESR ceramic
Taiyo Yuden
X5R Type
Low ESR ceramic
Sprague
circuit layout and grounding
As with any high-frequency switching power supply, circuit layout, hookup, and grounding are critical for proper
operation. Although this may be a relatively low-power, low-voltage design, these issues are still very important.
The MOSFET turn-on and turn-off times necessary to maintain high efficiency at high switching frequencies of
1 MHz or more result in high dv/dt and di/dts. This makes stray circuit inductance especially critical. In addition,
the high impedances associated with low-power designs, such as in the feedback divider, make them especially
susceptible to noise pickup.
layout
The component layout should be as tight as possible to minimize stray inductance. This is especially true of the
high-current paths, such as in series with the MOSFETs and the input and output filter capacitors.
The components associated with the feedback, compensation and timing should be kept away from the power
components (MOSFETs, inductor). Keep all components as close to the device pins as possible. Nodes that
are especially noise sensitive are the FB, RT and COMP pins.
24
www.ti.com
SLUS489 − OCTOBER 2001
APPLICATION INFORMATION
grounding
A ground plane is highly recommended. The GND pin of the TPS43000 should be close to the source of the
N-channel MOSFET, the input filter capacitor, and the output filter capacitor. The grounded end of the RT
resistor, the feedback divider resistor, and the SYNC/SD, CCS, CCM, PFM, and BUCK pins (when tied to ground
based on the application) form the signal ground and should be connected to the quietest location of the ground
plane (away from switching elements).
MOSFET gate resistors
The TPS43000 includes low-impedance CMOS output drivers for the two external MOSFET switches. The
NDRV output has a nominal pull-up resistance of 6.5 Ω and a nominal pull-down resistance of 2.25 Ω. The PDRV
output has a nominal pull-down resistance of 3.5 Ω and a nominal pull-up resistance of 2.5 Ω. For
high-frequency operation using low gate charge MOSFETs, no gate resistors are required. To reduce
high-frequency ringing at the MOSFET gates, low-value series gate resistors may be added. These should be
non-inductive resistors, with a value of 2 Ω to 10 Ω , depending on the frequency of operation. Lower values
result in better switching times, improving efficiency.
minimizing output ripple and noise spikes
The amount of output ripple is determined primarily by the type of output filter capacitor and how it is connected
in the circuit. In most cases, the ripple is dominated by the ESR (equivalent series resistance) and ESL
(equivalent series inductance) of the capacitor, rather than the actual capacitance value. Low ESR and ESL
capacitors are mandatory in achieving low output ripple. Surface-mount packages greatly reduce the ESL of
the capacitor, minimizing noise spikes. To further minimize high frequency spikes, a surface-mount ceramic
capacitor should be placed in parallel with the main filter capacitor. For best results, a capacitor should be
chosen whose self-resonant frequency is near the frequency of the noise spike. For high switching frequencies,
ceramic capacitors alone may be used, reducing size and cost.
For applications where the output ripple must be extremely low, a small LC filter may be added to the output.
The resonant frequency should be below the selected switching frequency, but above that of any dynamic loads.
The filter’s resonant frequency is given by:
f
RES
+
ǒ2 p
1
(L
C)
Ǔ
1ń2
(25)
where f is the frequency in Hz, L is the filter inductor value in Henries, and C is the filter capacitor value in Farads.
It is important to select an inductor rated for the maximum load current and with minimal resistance to reduce
losses. The capacitor should be a low-impedance type, such as a tantalum.
If an LC ripple filter is used, the feedback point can be taken before or after the filter, as long as the filter’s
resonant frequency is well above the loop crossover frequency. Otherwise, the additional phase lag makes the
loop unstable. The only advantage to connecting the feedback after the filter is that any small voltage drop
across the filter inductor is corrected for in the loop, providing the best possible voltage regulation. However,
the resistance of the inductor is usually low enough that the voltage drop is negligible.
www.ti.com
25
PACKAGE OPTION ADDENDUM
www.ti.com
27-Feb-2006
PACKAGING INFORMATION
Orderable Device
Status (1)
Package
Type
Package
Drawing
Pins Package Eco Plan (2)
Qty
TPS43000PW
ACTIVE
TSSOP
PW
16
90
Green (RoHS &
no Sb/Br)
CU NIPDAU
Level-1-260C-UNLIM
TPS43000PWG4
ACTIVE
TSSOP
PW
16
90
Green (RoHS &
no Sb/Br)
CU NIPDAU
Level-1-260C-UNLIM
TPS43000PWR
ACTIVE
TSSOP
PW
16
2000 Green (RoHS &
no Sb/Br)
CU NIPDAU
Level-1-260C-UNLIM
TPS43000PWRG4
ACTIVE
TSSOP
PW
16
2000 Green (RoHS &
no Sb/Br)
CU NIPDAU
Level-1-260C-UNLIM
Lead/Ball Finish
MSL Peak Temp (3)
(1)
The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in
a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2)
Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check
http://www.ti.com/productcontent for the latest availability information and additional product content details.
TBD: The Pb-Free/Green conversion plan has not been defined.
Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements
for all 6 substances, including the requirement that lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered
at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes.
Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and
package, or 2) lead-based die adhesive used between the die and leadframe. The component is otherwise considered Pb-Free (RoHS
compatible) as defined above.
Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame
retardants (Br or Sb do not exceed 0.1% by weight in homogeneous material)
(3)
MSL, Peak Temp. -- The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder
temperature.
Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is
provided. TI bases its knowledge and belief on information provided by third parties, and makes no representation or warranty as to the
accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and continues to take
reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on
incoming materials and chemicals. TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited
information may not be available for release.
In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI
to Customer on an annual basis.
Addendum-Page 1
PACKAGE MATERIALS INFORMATION
www.ti.com
14-Jul-2012
TAPE AND REEL INFORMATION
*All dimensions are nominal
Device
TPS43000PWR
Package Package Pins
Type Drawing
TSSOP
PW
16
SPQ
Reel
Reel
A0
Diameter Width (mm)
(mm) W1 (mm)
2000
330.0
12.4
Pack Materials-Page 1
6.9
B0
(mm)
K0
(mm)
P1
(mm)
5.6
1.6
8.0
W
Pin1
(mm) Quadrant
12.0
Q1
PACKAGE MATERIALS INFORMATION
www.ti.com
14-Jul-2012
*All dimensions are nominal
Device
Package Type
Package Drawing
Pins
SPQ
Length (mm)
Width (mm)
Height (mm)
TPS43000PWR
TSSOP
PW
16
2000
367.0
367.0
35.0
Pack Materials-Page 2
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