NSC LM26001BMHX

LM26001B
1.5A Switching Regulator with High Efficiency Sleep Mode
General Description
Features
The LM26001B is a switching regulator designed for the high
efficiency requirements of applications with stand-by modes.
The device features a low-current sleep mode to maintain efficiency under light-load conditions and current-mode control
for accurate regulation over a wide input voltage range. Quiescent current is reduced to 10 µA typically in shutdown mode
and less than 40 µA in sleep mode. Forced PWM mode is also
available to disable sleep mode.
The LM26001B can deliver up to 1.5A of continuous load current with a fixed current limit, through the internal N-channel
switch. The part has a wide input voltage range of 4.0V to 18V
and can operate with input voltages as low as 3V during line
transients.
Operating frequency is adjustable from 150 kHz to 500 kHz
with a single resistor and can be synchronized to an external
clock.
Other features include Power good, adjustable soft-start, enable pin, input under-voltage protection, and an internal bootstrap diode for reduced component count.
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High efficiency sleep mode
40 µA typical Iq in sleep mode
10 µA typical Iq in shutdown mode
3.0V minimum input voltage
4.0V to 18V continuous input range
2.0% reference accuracy
Cycle-by-cycle current limit
Adjustable Frequency (150 kHz to 500 kHz)
Synchronizable to an external clock
Power Good Flag
Forced PWM function
Adjustable Soft-start
TSSOP-16 exposed pad package
Thermal Shut Down
Applications
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Automotive Telematics
Navigation systems
In-Dash Instrumentation
Battery Powered Applications
Stand-by power for home gateways/set-top boxes
Typical Application Circuit
30001901
© 2008 National Semiconductor Corporation
300019
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LM26001B 1.5A Switching Regulator with High Efficiency Sleep Mode
May 29, 2008
LM26001B
Connection Diagram
30001902
Top View
16-Lead Exposed Pad TSSOP Package
Ordering Information
Order Number
Package Type
Package Drawing
Supplied As
LM26001BMH
TSSOP-16EXP
MXA16A
92 Units of Rail
LM26001BMHX
TSSOP-16EXP
MXA16A
2500 Units of Tape and Reel
Pin Descriptions
Pin #
Pin Name
1
VIN
Power supply input
Description
2
VIN
Power supply input
3
PGOOD
Power Good pin. An open drain output which goes high when the output voltage is greater than
92% of nominal.
4
EN
Enable is an analog level input pin. When pulled below 0.8V, the device enters shutdown mode.
5
SS
Soft-start pin. Connect a capacitor from this pin to GND to set the soft-start time.
6
COMP
7
FB
8
GND
Ground
Compensation pin. Connect to a resistor capacitor pair to compensate the control loop.
Feedback pin. Connect to a resistor divider between Vout and GND to set output voltage.
9
FREQ
Frequency adjust pin. Connect a resistor from this pin to GND to set the operating frequency.
10
FPWM
FPWM is a logic level input pin. For normal operation, connect to GND. When pulled high, sleep
mode operation is disabled.
11
SYNC
Frequency synchronization pin. Connect to an external clock signal for synchronized operation.
SYNC must be pulled low for non-synchronized operation.
12
VBIAS
Connect to an external 3V or greater supply to bypass the internal regulator for improved efficiency.
If not used, VBIAS should be tied to GND.
13
VDD
14
BOOT
15
SW
Switch pin. The source of the internal N-channel switch.
16
SW
Switch pin. The source of the internal N-channel switch.
EP
EP
Exposed Pad thermal connection. Connect to GND.
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The output of the internal regulator. Bypass with a minimum 1.0 µF capacitor.
Bootstrap capacitor pin. Connect a 0.1µF minimum ceramic capacitor from this pin to SW to
generate the gate drive bootstrap voltage.
2
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
Voltages from the indicated pins to GND:
VIN
-0.3V to 20V
SW (Note 7)
-0.5V to 20V
VDD
-0.3V to 7V
VBIAS
-0.3V to 10V
FB
-0.3V to 6V
BOOT
SW-0.3V to SW+7V
PGOOD
-0.3V to 7V
FREQ
-0.3V to 7V
SYNC
-0.3V to 7V
EN
-0.3V to 20V
FPWM
-0.3V to 7V
LM26001B
SS
Storage Temperature
Power Dissipation (Note 2)
Recommended Lead
Temperature
Vapor Phase (70s)
Infrared (15s)
ESD Susceptibility (Note 3)
Machine Model
Human Body Model
Charged Device Model
Absolute Maximum Ratings (Note 1)
-0.3V to 7V
-65°C to +150°C
2.6 W
215°C
220°C
200V
2KV
1kV
Operating Ratings
(Note 1)
Operating Junction Temp.
Supply Voltage (Note 4)
−40°C to 125°C
3.0V to 18V
Electrical Characteristics
Specifications in standard type are for TJ = 25°C only, and limits in boldface type apply
over the junction temperature (TJ) range of -40°C to +125°C. Unless otherwise stated, Vin=12V. Minimum and Maximum limits are
guaranteed through test, design, or statistical correlation. Typical values represent the most likely parametric norm at TJ = 25°C,
and are provided for reference purposes only. (Note 5)
Symbol
Parameter
Conditions
Min
Typ
Max
Unit
10.8
20
µA
38
70
µA
System
ISD (Note 6)
Shutdown Current
EN = 0V
Iq_Sleep_VB (Note 6)
Quiescent Current
Sleep mode, VBIAS = 5V
Iq_Sleep_VDD
Quiescent Current
Sleep mode, VBIAS = GND
75
125
µA
Iq_PWM_VB
Quiescent Current
PWM mode, VBIAS = 5V
150
230
µA
Iq_PWM_VDD
Quiescent Current
PWM mode, VBIAS = GND
0.65
0.85
mA
IBIAS_Sleep (Note 6)
Bias Current
Sleep mode, VBIAS = 5V
33
85
µA
IBIAS_PWM
Bias Current
PWM mode, VBIAS = 5V
0.5
0.70
mA
VFB
Feedback Voltage
5V < Vin < 18V
1.234
1.2589
V
IFB
FB Bias Current
ΔVOUT/ΔVIN
Vout Line Regulation
5V < Vin < 18V
0.001
%/V
ΔVOUT/ΔIOUT
Vout Load Regulation
0.8V < VCOMP < 1.15V
0.07
%
VDD
VDD Output Voltage
7V < Vin < 18V, IVDD= 0 mA to 5
mA
ISS_Source
Soft-Start Source Current
Vbias_th
VBIAS On Voltage
RDS(ON)
1.2093
±200
nA
5.50
5.95
6.50
V
1.5
2.2
4.6
µA
Specified at IBIAS = 92.5% of full
value
2.64
2.9
3.07
V
Switch On Resistance
Isw = 1A
0.12
0.2
0.42
Ω
Isw_off
Switch Off State Leakage Current
Vin = 18V, VSW = 0V
0.002
5.0
µA
fsw
Switching Frequency
RFREQ = 62k, 124k, 240k
±10
%
VFREQ
FREQ Voltage
fSW range
Switching Frequency Range
500
kHz
VSYNC
Sync Pin Threshold
1.6
V
Switching
1.0
150
SYNC rising
SYNC falling
Sync Pin Hysteresis
ISYNC
SYNC Leakage Current
FSYNC_UP
Upper frequency synchronization
range
1.2
0.8
V
1.1
114
mV
6
As compared to nominal fSW
3
nA
+30
%
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LM26001B
Symbol
Parameter
Conditions
Min
Typ
As compared to nominal fSW
Max
Unit
-20
%
FSYNC_DN
Lower frequency synchronization
range
TOFFMIN
Minimum Off-time
365
ns
TONMIN
Minimum On-time
155
ns
THSLEEP_HYS
Sleep Mode Threshold Hysteresis
VFB rising, % of THWAKE
101.2
%
THWAKE
Wake Up Threshold
Measured at falling FB, COMP =
0.6V
1.234
V
IBOOT
BOOT Pin Leakage Current
BOOT = 16V, SW = 10V
0.0006
5.0
µA
2.5
3.25
A
Protection
ILIMPK
Peak Current Limit
VFB_SC
Short Circuit Frequency Foldback
Threshold
Measured at FB falling
F_min_sc
Min Frequency in Foldback
VFB < 0.3V
VTH_PGOOD
Power Good Threshold
Measured at FB, PGOOD rising
1.80
PGOOD Hysteresis
0.87
V
71
89
2
95
7
8
IPGOOD_HI
PGOOD Leakage Current
PGOOD = 5V
0.2
RDS_PGOOD
PGOOD On Resistance
PGOOD sink current = 500 µA
64
VUVLO
Under-Voltage Lock-Out Threshold
Vin falling , shutdown, VDD =
VIN
2.60
Vin rising, soft-start, VDD = VIN
3.60
TSD
Thermal Shutdown Threshold
θJA
Thermal Resistance
Power dissipation = 1W, 0 lfpm
air flow
kHz
92
%
%
nA
Ω
2.9
3.20
3.9
4.20
V
160
°C
38
°C/W
Logic
VthEN
Enable Threshold voltage
0.8
Enable Hysteresis
IEN_Source
EN Source Current
VTH_FPWM
FPWM Threshold
IFPWM
FPWM Leakage Current
1.2
1.4
120
EN = 0V
4.5
0.8
FPWM = 5V
1.2
V
mV
µA
1.6
35
V
nA
EA
gm
Error Amp Trans-Conductance
ICOMP
COMP Source Current
VCOMP = 0.9V
56
µA
COMP Sink Current
VCOMP = 0.9V
56
µA
VCOMP
400
COMP Pin Voltage Range
0.64
670
1000
1.27
µmho
V
Note 1: Absolute Maximum Ratings indicate limits beyond which damage to the device may occur. Operating Ratings indicate conditions for which the device is
intended to be functional, but do not guarantee specific performance limits. For guaranteed specifications and test conditions, see the Electrical Characteristics.
Note 2: The maximum allowable power dissipation is a function of the maximum junction temperature, TJ_MAX, the junction-to-ambient thermal resistance, θJA,
and the ambient temperature, TA. The maximum allowable power dissipation at any ambient temperature is calculated using: PD_MAX = (TJ_MAX - TA) /θJA. The
maximum power dissipation of 2.6W is determined using TA = 25°C, θJA = 38°C/W, and TJ_MAX = 125°C.
Note 3: The human body model is a 100 pF capacitor discharged through a 1.5 kΩ resistor into each pin. The machine model is a 200pF capacitor discharged
directly into each pin. The charged device model is per JESD22-C101-C.
Note 4: Below 4.0V input, power dissipation may increase due to increased RDS(ON). Therefore, a minimum input voltage of 4.0V is required to operate continuously
within specification. A minimum of 3.9V (typical) is also required for startup.
Note 5: All room temperature limits are 100% production tested. All limits at temperature extremes are guaranteed through correlation using standard Statistical
Quality Control (SQC) methods. All limits are used to calculate Average Outgoing Quality Level (AOQL).
Note 6: Iq and ISD specify the current into the VIN pin. IBIAS is the current into the VBIAS pin when the VBIAS voltage is greater than 3V. All quiescent current
specifications apply to non-switching operation.
Note 7: The absolute maximum specification applies to DC voltage. An extended negative voltage limit of -2V applies for a pulse of up to 1µs, and -1V for a pulse
of up to 20µs.
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Unless otherwise specified the following conditions apply: Vin =
12V, TJ = 25°C.
VFB vs Temperature
VFB vs Vin
(IDC = 300 mA)
30001903
30001905
IQ and IVBIAS vs Temperature (Sleep Mode)
IQ and IVBIAS vs Temperature (PWM Mode)
30001906
30001904
UVLO Threshold vs Temperature (VDD = VIN)
Normalized Switching Frequency vs Temperature (300kHz)
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30001917
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LM26001B
Typical Performance Characteristics
LM26001B
Peak Current Limit vs Temperature
Short Circuit Foldback Frequency vs VFB
(325 kHz nominal)
30001915
30001912
Efficiency vs Load Current (330kHz)
Efficiency vs Load Current (500kHz)
30001908
30001909
Startup Waveforms
Load Transient Response
30001910
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30001952
6
LM26001B
Low Input Voltage Dropout
Nominal VOUT = 5V
30001953
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LM26001B
Block Diagram
30001918
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LM26001B
Operation Description
GENERAL
The LM26001B is a current mode PWM buck regulator. At the
beginning of each clock cycle, the internal high-side switch
turns on, allowing current to ramp up in the inductor. The inductor current is internally monitored during each switching
cycle. A control signal derived from the inductor current is
compared to the voltage control signal at the COMP pin, derived from the feedback voltage. When the inductor current
reaches the threshold, the high-side switch is turned off and
inductor current ramps down. While the switch is off, inductor
current is supplied through the catch diode. This cycle repeats
at the next clock cycle. In this way, duty cycle and output voltage are controlled by regulating inductor current. Current
mode control provides superior line and load regulation. Other
benefits include cycle by cycle current limiting and a simplified
compensation scheme. Typical PWM waveforms are shown
in Figure 1.
30001920
FIGURE 2. Sleep Mode Waveforms
25mA Load, Vin = 12V
In sleep mode, quiescent current is reduced to less than 40
µA when not switching. The DC sleep mode threshold can be
calculated according to the equation below:
Where Imin=Ilim/16 (2.5A/16 typically) and D=duty cycle, defined as (Vout+Vdiode)/Vin.
When load current increases above this limit, the LM26001B
is forced back into PWM operation. The sleep mode threshold
varies with frequency, inductance, and duty cycle as shown
in Figure 3.
30001919
FIGURE 1. PWM Waveforms
1A Load, Vin = 12V
SLEEP MODE
In light load conditions, the LM26001B automatically switches
into sleep mode for improved efficiency. As loading decreases, the voltage at FB increases and the COMP voltage decreases. When the COMP voltage reaches the 0.6V (typical)
clamp threshold, and the FB voltage rises 1% above nominal,
sleep mode is enabled and switching stops. The regulator remains in sleep mode until the FB voltage falls to the reset
threshold, at which point switching resumes. This 1% FB window limits the corresponding output ripple to approximately
1% of nominal output voltage. The sleep cycle will repeat until
load current is increased. Figure 2 shows typical switching
and output voltage waveforms in sleep mode.
30001922
FIGURE 3. Sleep Mode Threshold vs Vin
Vout = 3.3V
FPWM
Pulling the FPWM pin high disables sleep mode and forces
the LM26001B to always operate in PWM mode. Light load
efficiency is reduced in PWM mode, but switching frequency
remains stable. The FPWM pin can be connected to the VDD
pin to pull it high. In FPWM mode, under light load conditions,
the regulator operates in discontinuous conduction mode
(DCM) . In discontinuous conduction mode, current through
the inductor starts at zero and ramps up to its peak, then
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LM26001B
ramps down to zero again. Until the next cycle, the inductor
current remains at zero. At nominal load currents, in FPWM
mode, the device operates in continuous conduction mode,
where positive current always flows in the inductor. Typical
discontinuous operation waveforms are shown below.
Where tss is the desired soft-start time and Iss is the soft-start
source current. During soft-start, current limit and synchronization remain in effect, while sleep mode and frequency
foldback are disabled. Soft-start mode ends when the SS pin
voltage reaches 1.23V typical. At this point, output voltage
control is transferred to the FB pin and the SS pin is discharged.
CURRENT LIMIT
The peak current limit is set internally by directly measuring
peak inductor current through the internal switch. To ensure
accurate current sensing, VIN should be bypassed with a
minimum 1µF ceramic capacitor placed directly at the pin.
When the inductor current reaches the current limit threshold,
the internal FET turns off immediately allowing inductor current to ramp down until the next cycle. This reduction in duty
cycle corresponds to a reduction in output voltage.
The current limit comparator is disabled for less than 100ns
at the leading edge for increased immunity to switching noise.
Because the current limit monitors peak inductor current, the
DC load current limit threshold varies with inductance and
frequency. Assuming a minimum current limit of 1.80A, maximum load current can be calculated as follows:
30001923
FIGURE 4. Discontinuous Mode Waveforms
75mA Load, Vin = 12V
At very light load, in FPWM mode, the LM26001B may enter
sleep mode. This is to prevent an over-voltage condition from
occurring. However, the FPWM sleep threshold is much lower
than in normal operation.
Where Iripple is the peak-to-peak inductor ripple current, calculated as shown below:
ENABLE
The LM26001B provides a shutdown function via the EN pin
to disable the device when the output voltage does not need
to be maintained. EN is an analog level input with typically
120 mV of hysteresis. The device is active when the EN pin
is above 1.2V (typical) and in shutdown mode when EN is
below this threshold. When EN goes high, the internal VDD
regulator turns on and charges the VDD capacitor. When
VDD reaches 3.9V (typical), the soft-start pin begins to source
current. In shutdown mode, the VDD regulator shuts down
and total quiescent current is reduced to 10 µA (typical). Because the EN pin sources 4.5 µA (typical) of pull-up current,
this pin can be left open or connected to VIN for always-on
operation. When open, EN will be pulled up to VIN.
To find the worst case (lowest) current limit threshold, use the
maximum input voltage and minimum current limit specification.
During high over-current conditions, such as output short circuit, the LM26001B employs frequency foldback as a second
level of protection. If the feedback voltage falls below the short
circuit threshold of 0.9V, operating frequency is reduced,
thereby reducing average switch current. This is especially
helpful in short circuit conditions, when inductor current can
rise very high during the minimum on-time. Frequency reduction begins at 20% below the nominal frequency setting. The
minimum operating frequency in foldback mode is 71 kHz
typical.
If the FB voltage falls below the frequency foldback threshold
during frequency synchronized operation, the SYNC function
is disabled. Operating frequency versus FB voltage in short
circuit conditions is shown in the typical performance characteristics section.
In conditions where the on time is close to minimum (less than
200nsec typically), such as high input voltage and high
switching frequency, the current limit may not function properly. This is because the current limit circuit cannot reduce the
on-time below minimum which prevents entry into frequency
foldback mode. There are two ways to ensure proper current
limit and foldback operation under high input voltage conditions. First, the operating frequency can be reduced to increase the nominal on time. Second, the inductor value can
be increased to slow the current ramp and reduce the peak
over-current.
SOFT-START
The soft-start feature provides a controlled output voltage
ramp up at startup. This reduces inrush current and eliminates
output overshoot at turn-on. The soft-start pin, SS, must be
connected to GND through a capacitor. At power-on, enable,
or UVLO recovery, an internal 2.2 µA (typical) current charges
the soft-start capacitor. During soft-start, the error amplifier
output voltage is controlled by both the soft-start voltage and
the feedback loop. As the SS pin voltage ramps up, the duty
cycle increases proportional to the soft-start ramp, causing
the output voltage to ramp up. The rate at which the duty cycle
increases depends on the capacitance of the soft-start capacitor. The higher the capacitance, the slower the output
voltage ramps up. The soft-start capacitor value can be calculated with the following equation:
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RFREQ = (6.25 x 1010) x fSW-1.042
Where IQG is the gate drive current, calculated as:
IQG = (4.6 x 10-9) x fSW
Total supply input current varies according to load, system
efficiency, and operating frequency. To calculate minimum
input current during sleep mode, use Iq_Sleep_VB, and
IBIAS_SLEEP.
For input current in PWM mode, use the same equation, with
Iq_PWM_VB, and IBIAS_PWM.
If VBIAS is connected to ground, use the same equation with
the Ibias term eliminated and either Iq_Sleep_VDD or
Iq_PWM_VDD.
LOW VIN OPERATION AND UVLO
The LM26001B is designed to remain operational during short
line transients when input voltage may drop as low as 3.0V.
Minimum nominal operating input voltage is 4.0V. Below this
voltage, switch RDS(ON) increases, due to the lower gate drive
voltage from VDD. The minimum voltage required at VDD is
approximately 3.5V for normal operation within specification.
VDD can also be used as a pull-up voltage for functions such
as PGOOD and FPWM. Note that if VDD is used externally,
the pin is not recommended for loads greater than 1 mA.
If the input voltage approaches the nominal output voltage,
the duty cycle is maximized to hold up the output voltage. In
this mode of operation, once the duty cycle reaches its maximum, the LM26001B can skip a maximum of seven off pulses, effectively increasing the duty cycle and thus minimizing
the dropout from input to output. Typical off-pulse skipping
waveforms are shown below.
30001951
FIGURE 5. Swtiching Frequency vs RFREQ
The switching frequency can also be synchronized to an external clock signal using the SYNC pin. The SYNC pin allows
the operating frequency to be varied above and below the
nominal frequency setting. The adjustment range is from 30%
above nominal to 20% below nominal. External synchronization requires a 1.2V (typical) peak signal level at the SYNC
pin. The FREQ resistor must always be connected to initialize
the nominal operating frequency. The operating frequency is
synchronized to the falling edge of the SYNC input. When
SYNC goes low, the high-side switch turns on. This allows
any duty cycle to be used for the sync signal when synchronizing to a frequency higher than nominal. When synchronizing to a lower frequency, however, there is a minimum duty
cycle requirement for the SYNC signal, given in the equation
below:
Where fnom is the nominal switching frequency set by the
FREQ resistor, and fsync is a square wave. If the SYNC pin
is not used, it must be pulled low for normal operation. A
10kΩ pull-down resistor is recommended to protect against a
missing sync signal. Although the LM26001B is designed to
operate at up to 500 kHz, maximum load current may be limited at higher frequencies due to increased temperature rise.
See the Thermal Considerations section.
VBIAS
The VBIAS pin is used to bypass the internal regulator which
provides the bias voltage to the LM26001B. When the VBIAS
pin is connected to a voltage greater than 3V, the internal
regulator automatically switches over to the VBIAS input. This
reduces the current into VIN (Iq) and increases system efficiency. Using the VBIAS pin has the added benefit of reducing
power dissipation within the device.
30001929
FIGURE 6. Off-pulse Skipping Waveforms
Vin = 3.5V, Vnom = 3.3V, fnom = 305kHz
UVLO is sensed at both VIN and VDD, and is activated when
either voltage falls below 2.9V (typical). Although VDD is typ11
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LM26001B
For most applications where 3V < Vout < 10V, VBIAS can be
connected to Vout. If not used, VBIAS should be tied to GND.
If VBIAS drops below 2.9V (typical), the device automatically
switches over to supply the internal bias voltage from Vin.
Total device input current is the sum of Iq, gate drive current,
and VBIAS current, plus some negligible current into the FB
pin. Total minimum input supply current can be calculated as
shown below:
FREQUENCY ADJUSTMENT AND SYNCHRONIZATION
The switching frequency of the LM26001B can be adjusted
between 150 kHz and 500 kHz using a single external resistor. This resistor is connected from the FREQ pin to ground
as shown in the typical application. The resistor value can be
calculated with the following empirically derived equation:
LM26001B
ically less than 200mV below VIN, it will not discharge through
VIN. Therefore when the VIN voltage drops rapidly, VDD may
remain high, especially in sleep mode. For fast line voltage
transients, using a larger capacitor at the VDD pin can help
to hold off a UVLO shutdown by extending the VDD discharge
time. By holding up VDD, a larger cap can also reduce the
RDS(ON) (and dropout voltage) in low VIN conditions. Alternately, under heavy loading the VDD voltage can fall several
hundred mV below VIN. In this case, UVLO may be triggered
by VDD even though the VIN voltage is above the UVLO
threshold.
When UVLO is activated the LM26001B enters a standby
state in which VDD remains charged. As input voltage and
VDD voltage rise above 3.9V (typical) the device will restart
from softstart mode.
drain MOSFET, which remains open while the output voltage
is within operating range. PGOOD goes low (low impedance
to ground) when the output falls below 85% of nominal or EN
is pulled low. When the output voltage returns to within 92%
of nominal, as measured at the FB pin, PGOOD returns to a
high state. For improved noise immunity, there is a 5us delay
between the PGOOD threshold and the PGOOD pin going
low.
Design Information
EXAMPLE CIRCUIT
Figure 7 shows a complete typical application schematic. The
components have been selected based on the design criteria
given in the following sections.
PGOOD
A power good pin, PGOOD, is available to monitor the output
voltage status. The pin is internally connected to an open
30001930
FIGURE 7. Example Circuit
1.5A Max, 305 kHz
pared to load current, or ripple content, is defined as Iripple/
Iload. Ripple content should be less than 40%. Inductor ripple
current, Iripple, can be calculated as shown below:
SETTING OUTPUT VOLTAGE
The output voltage is set by the ratio of a voltage divider at
the FB pin as shown in the typical application. The resistor
values can be determined by the following equation:
Larger ripple content increases losses in the inductor and reduces the effective current limit.
Larger inductance values result in lower output ripple voltage
and higher efficiency, but a slightly degraded transient response. Lower inductance values allow for smaller case size,
but the increased ripple lowers the effective current limit
threshold.
Remember that inductor value also affects the sleep mode
threshold as shown in Figure 3.
When choosing the inductor, the saturation current rating
must be higher than the maximum peak inductor current and
the RMS current rating should be higher than the maximum
load current. Peak inductor current, Ipeak, is calculated as:
Where Vfb = 1.234V typically.
A maximum value of 150kΩ is recommended for the sum of
R1 and R2.
As input voltage decreases towards the nominal output voltage, the LM26001B can skip up to seven off-pulses as described in the Low Vin Operation section. In low output voltage
applications, if the on-time reaches TonMIN, the device will
skip on-pulses to maintain regulation. There is no limit to the
number of pulses that are skipped. In this mode of operation,
however, output ripple voltage may increase slightly.
INDUCTOR
The output inductor should be selected based on inductor
ripple current. The amount of inductor ripple current comwww.national.com
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For example, at a maximum load of 1.5A and a ripple content
of 33%, peak inductor current is equal to 1.75A which is safely
below the minimum current limit of 1.80A. By increasing the
inductor size, ripple content and peak inductor current are
lowered, which increases the current limit margin.
The size of the output inductor can also be determined using
the desired output ripple voltage, Vrip. The equation to determine the minimum inductance value based on Vrip is as
follows:
For noise suppression, a ceramic capacitor in the range of 1.0
µF to 10 µF should be placed as close as possible to the VIN
pin.
A larger, high ESR input capacitor should also be used. This
capacitor is recommended for damping input voltage spikes
during power on and for holding up the input voltage during
transients. In low input voltage applications, line transients
may fall below the UVLO threshold if there is not enough input
capacitance. Both tantalum and electrolytic type capacitors
are suitable for the bulk capacitor. However, large tantalums
may not be available for high input voltages and their working
voltage must be derated by at least 2X.
Where Re is the ESR of the output capacitors, and Vrip is a
peak-to-peak value. This equation assumes that the output
capacitors have some amount of ESR. It does not apply to
ceramic output capacitors.
If this method is used, ripple content should still be verified to
be less than 40%.
OUTPUT CAPACITOR
The primary criterion for selecting an output capacitor is
equivalent series resistance, or ESR.
ESR (Re) can be selected based on the requirements for output ripple voltage and transient response. Once an inductor
value has been selected, ripple voltage can be calculated for
a given Re using the equation above for Lmin. Lower ESR
values result in lower output ripple.
Re can also be calculated from the following equation:
BOOTSTRAP
The drive voltage for the internal switch is supplied via the
BOOT pin. This pin must be connected to a ceramic capacitor,
Cboot, from the switch node, shown as C4 in the typical application. The LM26001B provides the VDD voltage internally,
so no external diode is needed. A minimum value of 0.1 uF is
recommended for Cboot. Smaller values may result in insufficient hold up time for the drive voltage and increased power
dissipation.
During low Vin operation, when the on-time is extended, the
bootstrap capacitor is at risk of discharging. If the Cboot capacitor is discharged below approximately 2.5V, the
LM26001B enters a high frequency re-charge mode. The
Cboot cap is re-charged via the LG synchronous FET shown
in the block diagram. Switching returns to normal when the
Cboot cap has been recharged.
Where ΔVt is the allowed voltage excursion during a load
transient, and ΔIt is the maximum expected load transient.
If the total ESR is too high, the load transient requirement
cannot be met, no matter how large the output capacitance.
If the ESR criteria for ripple voltage and transient excursion
cannot be met, more capacitors should be used in parallel.
For non-ceramic capacitors, the minimum output capacitance
is of secondary importance, and is determined only by the
load transient requirement.
If there is not enough capacitance, the output voltage excursion will exceed the maximum allowed value even if the
maximum ESR requirement is met. The minimum capacitance is calculated as follows:
CATCH DIODE
When the internal switch is off, output current flows through
the catch diode. Alternately, when the switch is on, the diode
sees a reverse voltage equal to Vin. Therefore, the important
parameters for selecting the catch diode are peak current and
peak inverse voltage. The average current through the diode
is given by:
IDAVE = Iload x (1-D)
Where D is the duty cycle, defined as Vout/Vin. The catch
diode conducts the largest currents during the lowest duty
cycle. Therefore IDAVE should be calculated assuming maximum input voltage. The diode should be rated to handle this
current continuously. For over-current or short circuit conditions, the catch diode should be rated to handle peak currents
equal to the peak current limit.
The peak inverse voltage rating of the diode must be greater
than maximum input voltage.
A Schottky diode must be used. It's low forward voltage maximizes efficiency and BOOT voltage, while also protecting the
SW pin against large negative voltage spikes
It is assumed the total ESR, Re, is no greater than ReMAX.
Also, it is assumed that L has already been selected.
Generally speaking, the output capacitance requirement decreases with Re, ΔIt, and L. A typical value greater than 100
µF works well for most applications.
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LM26001B
INPUT CAPACITOR
In a switching converter, very fast switching pulse currents
are drawn from the input rail. Therefore, input capacitors are
required to reduce noise, EMI, and ripple at the input to the
LM26001B. Capacitors must be selected that can handle both
the maximum ripple RMS current at highest ambient temperature as well as the maximum input voltage. The equation for
calculating the RMS input ripple current is shown below:
LM26001B
COMPENSATION
The purpose of loop compensation is to ensure stable operation while maximizing dynamic performance. Stability can be
analyzed with loop gain measurements, while dynamic performance is analyzed with both loop gain and load transient
response. Loop gain is equal to the product of control-output
transfer function (power stage) and the feedback transfer
function (the compensation network).
For stability purposes, our target is to have a loop gain slope
that is -20dB /decade from a very low frequency to beyond
the crossover frequency. Also, the crossover frequency
should not exceed one-fifth of the switching frequency, i.e. 60
kHz in the case of 300 kHz switching frequency.
For dynamic purposes, the higher the bandwidth, the faster
the load transient response. A large DC gain means high DC
regulation accuracy (i.e. DC voltage changes little with load
or line variations). To achieve this loop gain, the compensation components should be set according to the shape of the
control-output bode plot. A typical plot is shown in Figure 8
below.
30001939
FIGURE 9. Feedback Transfer Function
The control-output corner frequencies can be determined approximately by the following equations:
Where Co is the output capacitance, Ro is the load resistance,
Re is the output capacitor ESR, and fsw is the switching frequency. The effects of slope compensation and current sense
gain are included in this equation. However, the equation is
an approximation intended to simplify loop compensation calculations. To derive the exact transfer function, use 0.2V/V
sense amp gain and 36mVp-p slope compensation.
Since fp is determined by the output network, it shifts with
loading. Determine the range of frequencies (fpmin/max)
across the expected load range. Then determine the compensation values as described below and shown in Figure 10.
30001938
FIGURE 8. Control-Output Transfer Function
The control-output transfer function consists of one pole (fp),
one zero (fz), and a double pole at fn (half the switching frequency).
Referring to Figure 8, the following should be done to create
a -20dB /decade roll-off of the loop gain:
1. Place a pole at 0Hz (fpc)
2. Place a zero at fp (fzc)
3. Place a second pole at fz (fpc1)
The resulting feedback (compensation) bode plot is shown
below in Figure 9. Adding the control-output response to the
feedback response will then result in a nearly continuous
-20db/decade slope.
30001943
FIGURE 10. Compensation Network
1. The compensation network automatically introduces a low
frequency pole (fpc), which is close to 0Hz.
2. Once the fp range is determined, R5 should be calculated
using:
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14
Where B is the desired feedback gain in v/v between fp and
fz, and gm is the transconductance of the error amplifier. A
gain value around 10dB (3.3v/v) is generally a good starting
point. Bandwidth increases with increasing values of R5.
3. Next, place a zero (fzc) near fp using C8. C8 can be determined with the following equation:
The selected value of C8 should place fzc within a decade
above or below fpmax, and not less than fpmin. A higher C8
value (closer to fpmin) generally provides a more stable loop,
but too high a value will slow the transient response time.
Conversely, a smaller C8 value will result in a faster transient
response, but lower phase margin.
4. A second pole (fpc1) can also be placed at fz. This pole can
be created with a single capacitor, C9. The minimum value
for this capacitor can be calculated by:
C9 may not be necessary in all applications. However if the
operating frequency is being synchronized below the nominal
frequency, C9 is recommended. Although it is not required for
stability, C9 is very helpful in suppressing noise.
A phase lead capacitor can also be added to increase the
phase and gain margins. The phase lead capacitor is most
helpful for high input voltage applications or when synchronizing to a frequency greater than nominal. This capacitor,
shown as C10 in Figure 10, should be placed in parallel with
the top feedback resistor, R1. C10 introduces an additional
zero and pole to the compensation network. These frequencies can be calculated as shown below:
30001949
FIGURE 11. Example PCB Layout
It is a good practice to connect the EP, GND pin, and small
signal components (COMP, FB, FREQ) to a separate ground
plane, shown in Figure 11 as EP GND, and in the schematics
as a signal ground symbol. Both the exposed pad and the
GND pin must be connected to ground. This quieter plane
should be connected to the high current ground plane at a
quiet location, preferably near the Vout ground as shown by
the dashed line in Figure 11.
The EP GND plane should be made as large as possible,
since it is also used for thermal dissipation. Several vias can
be placed directly below the EP to increase heat flow to other
layers when they are available. The recommended via hole
diameter is 0.3mm.
The trace from the FB pin to the resistor divider should be
short and the entire feedback trace must be kept away from
the inductor and switch node. See Application Note AN-1229
for more information regarding PCB layout for switching regulators.
A phase lead capacitor will boost loop phase around the region of the zero frequency, fzff. fzff should be placed somewhat below the fpz1 frequency set by C9. However, if C10 is
too large, it will have no effect.
PCB Layout
Good board layout is critical for switching regulators such as
the LM26001B. First, the ground plane area must be sufficient
for thermal dissipation purposes, and second, appropriate
guidelines must be followed to reduce the effects of switching
noise.
Switch mode converters are very fast switching devices. In
such devices, the rapid increase of input current combined
with parasitic trace inductance generates unwanted Ldi/dt
noise spikes at the SW node and also at the VIN node. The
15
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LM26001B
magnitude of this noise tends to increase as the output current
increases. This parasitic spike noise may turn into electromagnetic interference (EMI), and can also cause problems in
device performance. Therefore, care must be taken in layout
to minimize the effect of this switching noise.
The current sensing circuit in current mode devices can be
easily affected by switching noise. This noise can cause duty
cycle jitter which leads to increased spectral noise. Although
the LM26001B has 100ns blanking time at the beginning of
every cycle to ignore this noise, some noise may remain after
the blanking time. Following the important guidelines below
will help minimize switching noise and its effect on current
sensing.
The switch node area should be as small as possible. The
catch diode, input capacitors, and output capacitors should
be grounded to a large ground plane, with the bulk input capacitor grounded as close as possible to the catch diode
anode. Additionally, the ground area between the catch diode
and bulk input capacitor is very noisy and should be somewhat isolated from the rest of the ground plane.
A ceramic input capacitor must be connected as close as
possible to the VIN pin and grounded close to the GND pin.
Often this capacitor is most easily located on the bottom side
of the pcb. If placement close to the GND pin is not practical,
the ceramic input capacitor can also be grounded close to the
catch diode ground. The above layout recommendations are
illustrated below in Figure 11.
LM26001B
Given this total power dissipation, junction temperature can
be calculated as follows:
Thermal Considerations and TSD
Although the LM26001B has a built in current limit, at ambient
temperatures above 80°C, device temperature rise may limit
the actual maximum load current. Therefore, temperature rise
must be taken into consideration to determine the maximum
allowable load current.
Temperature rise is a function of the power dissipation within
the device. The following equations can be used to calculate
power dissipation (PD) and temperature rise, where total PD
is the sum of FET switching losses, FET DC losses, drive
losses, Iq, and VBIAS losses:
Tj = Ta + (PDTOTAL x θJA)
Where θJA=38°C/W (typically) when using a multi-layer board
with a large copper plane area. θJA varies with board type and
metallization area.
To calculate the maximum allowable power dissipation, assume Tj = 125°C. To ensure that junction temperature does
not exceed the maximum operating rating of 125°C, power
dissipation should be verified at the maximum expected operating frequency, maximum ambient temperature, and minimum and maximum input voltage. The calculated maximum
load current is based on continuous operation and may be
exceeded during transient conditions.
If the power dissipation remains above the maximum allowable level, device temperature will continue to rise. When the
junction temperature exceeds its maximum, the LM26001B
engages Thermal Shut Down (TSD). In TSD, the part remains
in a shutdown state until the junction temperature falls to within normal operating limits. At this point, the device restarts in
soft-start mode.
PDTOTAL = PswAC + PswDC + PQG + PIq + PVBIAS
PswDC = D x Iload2 x (0.2 + 0.00065 x (Tj - 25))
PQG = Vin x 4.6 x 10-9 x fsw
PIq = Vin x Iq
PVBIAS = Vbias x IVBIAS
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16
LM26001B
Physical Dimensions inches (millimeters) unless otherwise noted
eTSSOP-16 Package
16-Lead Exposed Pad TSSOP Package
NS Package Number MXA16A
17
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LM26001B 1.5A Switching Regulator with High Efficiency Sleep Mode
Notes
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