NSC LM2619ATL

LM2619
500mA Sub-Miniature Step-Down DC-DC Converter
General Description
Key Specifications
The LM2619 step down DC-DC converter is optimized for
powering circuits from a single Lithium-Ion cell. It steps down
an input voltage of 2.8V to 5.5V to an output of 1.5V to 3.6V
at up to 500mA. Output voltage is set using resistor feedback
dividers.
The device offers three modes for mobile phones and similar
portable applications. Fixed-frequency PWM mode minimizes RF interference. A SYNC input allows synchronizing
the switching frequency in a range of 500kHz to 1MHz. Low
current hysteretic PFM mode reduces quiescent current to
160µA (typ.). Shutdown mode turns the device off and reduces battery consumption to 0.02µA (typ.).
Current limit and thermal shutdown features protect the device and system during fault conditions.
The LM2619 is available in a 10 bump micro SMD package.
This packaging uses National’s chip-scale micro SMD technology and offers the smallest possible size. A high switching
frequency (600kHz) allows use of tiny surface-mount components.
The device features external compensation to tailor the response to a wide range of operating conditions.
Operates from a single LiION cell (2.8V to 5.5V)
Output voltage (1.5V to 3.6V)
± 1% DC feedback voltage precision
500mA maximum load capability
600µA typ PWM mode quiescent current
0.02µA typ shutdown current
600kHz PWM switching frequency
SYNC input for PWM mode frequency synchronization
from 500kHz to 1MHz
n High efficiency (96% typ at 3.9VIN, 3.6VOUT and 200mA)
in PWM mode from internal synchronous rectification
n 100% Maximum Duty Cycle for Lowest Dropout
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Features
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Sub-miniature 10-bump thin micro SMD package
Uses small ceramic capacitors
5mV typ PWM mode output voltage ripple(COUT = 22µF)
Internal soft start
Current overload protection
Thermal Shutdown
External compensation
Applications
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© 2003 National Semiconductor Corporation
DS200574
Mobile Phones
Hand-Held Radios
RF PC Cards
Wireless LAN Cards
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LM2619 500mA Sub-Miniature Step-Down DC-DC Converter
October 2003
LM2619
Typical Application Circuits
20057401
FIGURE 1. Typical Circuit for 1.8V Output Voltage
20057402
FIGURE 2. Typical Circuit for 2.5V Output Voltage
20057403
FIGURE 3. Typical Circuit for 1.5V Output Voltage
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LM2619
Connection Diagrams
10-Bump micro SMD Package
20057404
20057405
Top View
Bottom View
Ordering Information
Order Number
LM2619ATL
LM2619ATLX
Package Type
NSC Package
Marking (*)
10-bump Wafer Level Chip Scale
(micro SMD)
Supplied As
XYTT S76A
250 Tape and Reel
XYTT S76A
3000 Tape and Reel
(*) XY - denotes the date code marking (2 digit) in production
(*) TT - refers to die run/lot traceability for production
(*) S - product line designator
Package markings may change over the course of production.
Pin Description
Pin Number
Pin Name
Function
A1
FB
B1
EANEG
Inverting input of error amplifier.
Feedback Analog Input.
C1
EAOUT
Output of error amplifier.
D1
SYNC/MODE
D2
EN
D3
PGND
C3
SW
B3
PVIN
Power Supply Voltage Input to the internal PFET switch. Connect to the input filter
capacitor.
A3
VDD
Analog Supply Input. If board layout is not optimum, an optional 0.1µF ceramic capacitor
is suggested.
A2
SGND
Synchronization Input. Use this digital input for frequency selection or modulation control.
Set:
SYNC/MODE = high for low-noise 600kHz PWM mode
SYNC/MODE = low for low-current PFM mode
SYNC/MODE = a 500kHz–1MHz external clock for synchronization in PWM mode. (See
Synchronization and Operating Modes in the Device Information section.)
Enable Input. Set this Schmitt trigger digital input high for normal operation. For shutdown,
set low. Set EN low during system power-up and other low supply voltage conditions.
(See Shutdown Mode in the Device Information section.)
Power Ground.
Switching Node connection to the internal PFET switch and NFET synchronous rectifier.
Connect to an inductor with a saturation current rating that exceeds the max Switch Peak
Current Limit of the LM2619.
Analog and Control Ground.
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LM2619
Absolute Maximum Ratings
(Note 1)
Storage Temperature Range
Lead Temperature
(Soldering, 10 sec.)
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
PVIN, VDD to SGND
EN, EAOUT, EANEG, SYNC/MODE
to SGND
FB, SW
260˚C
Junction Temperature (Note 2)
−0.2V to +6V
PGND to SGND, PVIN to VDD
−45˚C to +150˚C
−25˚C to +125˚C
± 2 kV
Minimum ESD Rating
−0.2V to +0.2V
(Human Body Model, C = 100 pF, R = 1.5 kΩ)
Thermal Resistance (θJA) (Note 3)
140˚C/W
−0.2V to +6V
(GND −0.2V) to
(VDD +0.2V)
Electrical Characteristics
Specifications with standard typeface are for TA = TJ = 25˚C, and those in boldface type apply over the full Operating Temperature Range of TA = TJ = −25˚C to +85˚C. Unless otherwise specified, PVIN = VDD = EN = SYNC/MODE = 3.6V.
Symbol
Parameter
Conditions
Min
Typ
Max
Units
2.8
3.6
5.5
V
1.485
1.50
1.515
V
VIN
Input Voltage Range
VFB
Feedback Voltage
VHYST
PFM Comparator Hysteresis
Voltage
PFM Mode (SYNC/MODE =
0V) (Note 5)
ISHDN
Shutdown Supply Current
VIN = 3.6V, EN = 0V
0.02
3
µA
IQ1_PWM
DC Bias Current into VDD
SYNC/MODE = VIN
FB = 2V
600
725
µA
SYNC/MODE = 0V
FB = 2V
160
195
µA
IQ2_PFM
PVIN = VDD = VIN (Note 4)
24
mV
RDSON (P)
Pin-Pin Resistance for
P FET
395
550
mΩ
RDSON (N)
Pin-Pin Resistance for
N FET
330
500
mΩ
RDSON (TC)
FET Resistance
Temperature Coefficient
0.5
ILIM
Switch Peak Current Limit
(Note 6)
VIH
Logic High Input, EN,
SYNC/MODE
VIL
Logic Low Input, EN,
SYNC/MODE
FSYNC
SYNC/MODE Clock
Frequency Range
(Note 7)
FOSC
Internal Oscillator
Frequency
PWM Mode
Tmin
Minimum ON-Time of PFET
Switch in PWM Mode
620
0.4
810
1100
mA
0.95
1.3
V
0.80
500
468
%/C
600
200
V
1000
kHz
732
kHz
ns
Note 1: Absolute Maximum Ratings indicate limits beyond which damage to the device may occur. Operating Ratings indicate conditions for which the device is
functional, but device specifications may not be guaranteed. For guaranteed specifications and associated test conditions, see the Min and Max limits and Conditions
in the Electrical Characteristics table. Typical (typ) specifications are mean or average values at 25˚C and are not guaranteed.
Note 2: Thermal shutdown will occur if the junction temperature exceeds 150˚C.
Note 3: Thermal resistance specified with 2 layer PCB (0.5/0.5 oz. cu).
Note 4: The LM2619 is designed for mobile phone applications where turn-on after system power-up is controlled by the system controller. Thus, it should be kept
in shutdown by holding the EN pin low until the input voltage exceeds 2.8V.
Note 5: The hysteresis voltage is the minimum voltage swing on the FB pin that causes the internal feedback and control circuitry to turn the internal PFET switch
on and then off during PFM mode. When resistor dividers are used like in the operating circuit of Figure 4, the hysteresis at the output will be the value of the
hysteresis at the feedback pin times the resistor divider ratio. In this case, 24mV (typ) x ((46.4k + 33.2k)/33.2k).
Note 6: Current limit is built-in, fixed, and not adjustable. If the current limit is reached while the voltage at the FB pin is pulled below 0.7V, the internal PFET switch
turns off for 2.5µs to allow the inductor current to diminish.
Note 7: SYNC driven with an external clock switching between VIN and GND. When an external clock is present at SYNC; the IC is forced to be in PWM mode at
the external clock frequency. The LM2619 synchronizes to the rising edge of the external clock.
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LM2619ATL, Circuit of Figure 3, VIN = 3.6V, TA = 25˚C, unShutdown Quiescent Current vs Temperature
(Circuit in Figure 3)
Quiescent Supply Current vs Supply Voltage
20057408
20057422
Output Voltage vs Supply Voltage
(VOUT = 1.5V, PFM MODE)
Output Voltage vs Supply Voltage
(VOUT = 1.5V, PWM MODE)
20057409
20057410
Output Voltage vs Output Current
(VOUT = 1.5V, PFM MODE)
Output Voltage vs Output Current
(VOUT = 1.5V, PWM MODE)
20057411
20057413
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LM2619
Typical Performance Characteristics
less otherwise noted.
LM2619
Typical Performance Characteristics LM2619ATL, Circuit of Figure 3, VIN = 3.6V, TA = 25˚C, unless
otherwise noted. (Continued)
Output Voltage vs Output Current
(VOUT = 3.6V, PWM MODE)
(Circuit in Figure 4)
Dropout Voltage vs Output Current
(VOUT = 3.6V, PWM MODE)
(Circuit in Figure 4)
20057432
20057412
Switching Frequency vs Temperature
(Circuit in Figure 3, PWM MODE)
Feedback Bias Current vs Temperature
(Circuit in Figure 3)
20057423
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20057431
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Efficiency vs Output Current
(VOUT = 1.5V, PWM MODE)
Efficiency vs Output Current
(VOUT = 1.5V, PWM MODE, with Diode)
20057415
20057416
Efficiency vs Output Current
(VOUT = 3.6V, PWM MODE, with Diode)
(Circuit in Figure 4)
Efficiency vs Output Current
(VOUT = 3.6V, PWM MODE)
(Circuit in Figure 4)
20057417
20057418
duces quiescent current to 160µA typ. to maximize battery
life. Shutdown mode turns the device off and reduces battery
consumption to 0.02µA (typ).
DC PWM mode feedback voltage precision is ± 1%. Efficiency is typically 96% for a 200mA load with 3.6V output,
3.9V input. The efficiency can be further increased by using
a schottky diode like MBRM120L as shown in Figure 4. PWM
mode quiescent current is 600µA typ. The output voltage can
be set from 1.5V to 3.6V by using external feedback resistors.
Additional features include soft-start, current overload protection, over voltage protection and thermal shutdown protection.
The LM2619 is constructed using a chip-scale 10-pin thin
micro SMD package. This package offers the smallest possible size, for space-critical applications such as cell phones,
where board area is an important design consideration. Use
of a high switching frequency (600kHz) reduces the size of
Device Information
The LM2619 is a simple, step-down DC-DC converter optimized for powering circuits in mobile phones, portable communicators, and similar battery powered RF devices. It is
based on a current-mode buck architecture, with synchronous rectification in PWM mode for high efficiency. It is
designed for a maximum load capability of 500mA in PWM
mode. Maximum load range may vary from this depending
on input voltage, output voltage and the inductor chosen.
The device has all three of the pin-selectable operating
modes required for powering circuits in mobile phones and
other sophisticated portable devices with complex power
management needs. Fixed-frequency PWM operation offers
full output current capability at high efficiency while minimizing interference with sensitive IF and data acquisition circuits. During standby operation, hysteretic PFM mode re-
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LM2619
Typical Performance Characteristics LM2619ATL, Circuit of Figure 3, VIN = 3.6V, TA = 25˚C, unless
otherwise noted. (Continued)
LM2619
Device Information
Assembly and Use in the Application Information section.) Its
fine bump-pitch requires careful board design and precision
assembly equipment.
(Continued)
external components. Board area required for implementation is only 0.58in2 (375mm2).
Use of a micro-SMD package requires special design considerations for implementation. (See Micro SMD Package
20057406
FIGURE 4. Typical Operating Circuit for 3.6V Output Voltage
CIRCUIT OPERATION
Referring to Figure 4, Figure 5, Figure 6 and Figure 7,
transferred back into the circuit and depleted, the inductor
current ramps down with a slope of VOUT/L. If the inductor
current reaches zero before the next cycle, the synchronous
rectifier is turned off to prevent current reversal. The output
filter capacitor stores charge when the inductor current is
high, and releases it when low, smoothing the voltage across
the load.
The output voltage is regulated by modulating the PFET
switch on time to control the average current sent to the load.
The effect is identical to sending a duty-cycle modulated
rectangular wave formed by the switch and synchronous
rectifier at SW to a low-pass filter formed by the inductor and
output filter capacitor. The output voltage is equal to the
average voltage at the SW pin.
the LM2619 operates as follows. During the first part of each
switching cycle, the control block in the LM2619 turns on the
internal PFET switch. This allows current to flow from the
input through the inductor to the output filter capacitor and
load. The inductor limits the current to a ramp with a slope of
(VIN–VOUT)/L, by storing energy in a magnetic field. During
the second part of each cycle, the controller turns the PFET
switch off, blocking current flow from the input, and then
turns the NFET synchronous rectifier on. In response, the
inductor’s magnetic field collapses, generating a voltage that
forces current from ground through the synchronous rectifier
to the output filter capacitor and load. As the stored energy is
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LM2619
Device Information
(Continued)
20057407
FIGURE 5. Simplified Functional Diagram
PWM OPERATION
While in PWM (Pulse Width Modulation) mode, the output
voltage is regulated by switching at a constant frequency
and then modulating the energy per cycle to control power to
the load. Energy per cycle is set by modulating the PFET
switch on-time pulse-width to control the peak inductor current. This is done by comparing the signal from the currentsense amplifier with a slope compensated error signal from
the voltage-feedback error amplifier. At the beginning of
each cycle, the clock turns on the PFET switch, causing the
inductor current to ramp up. When the current sense signal
ramps past the error amplifier signal, the PWM comparator
turns off the PFET switch and turns on the NFET synchronous rectifier, ending the first part of the cycle. If an increase
in load pulls the output voltage down, the error amplifier
output increases, which allows the inductor current to ramp
higher before the comparator turns off the PFET. This increases the average current sent to the output and adjusts
for the increase in the load.
Before going to the PWM comparator, the error signal is
summed with a slope compensation ramp from the oscillator
for stability of the current feedback loop. During the second
part of the cycle, a zero crossing detector turns off the NFET
synchronous rectifier if the inductor current ramps to zero.
The minimum on time of the PFET in PWM mode is about
200ns.
PWM Mode Switching Waveform
20057425
A: Inductor Current, 500mA/div
B: SW Pin, 2V/div
C: VOUT, 10mV/div, AC Coupled
FIGURE 6.
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LM2619
Device Information
0.4V) selects hysteretic voltage-mode PFM operation. PFM
mode is optimized for reducing power consumption and
extending battery life when the load is in a low-power
standby mode. In PFM mode, quiescent current into the VDD
pin is 160µA typ. In contrast, PWM mode VDD-pin quiescent
current is 600µA typ.
(Continued)
PFM Mode Switching Waveform
PWM operation is intended for use with loads of 50mA or
more, when low noise operation is desired. Below 100mA,
PFM operation can be used to allow precise regulation, and
reduced current consumption. The LM2619 has an overvoltage feature that prevents the output voltage from rising
too high, when the device is left in PWM mode under lowload conditions. See Overvoltage Protection, for more information.
Switch modes with the SYNC/MODE pin, using a signal with
a slew rate faster than 5V/100µs. Use a comparator, Schmitt
trigger or logic gate to drive the SYNC/MODE pin. Do not
leave the pin floating or allow it to linger between thresholds.
These measures will prevent output voltage errors in response to an indeterminate logic state. The LM2619
switches on each rising edge of SYNC. Ensure a minimum
load to keep the output voltage in regulation when switching
modes frequently.
20057426
A: Inductor Current, 500mA/div
B: SW Pin, 2V/div
C: VOUT, 50mV/div, AC Coupled
FREQUENCY SYNCHRONIZATION
The SYNC/MODE input can also be used for frequency
synchronization. During synchronization, the LM2619 initiates cycles on the rising edge of the clock. When synchronized to an external clock, it operates in PWM mode. The
device can synchronize to a 50% duty-cycle clock over
frequencies from 500kHz to 1MHz. If a different duty cycle is
used other than 50% the range for acceptable duty cycles is
30% to 70%.
Use the following waveform and duty cycle guidelines when
applying an external clock to the SYNC/MODE pin. Clock
under/overshoot should be less than 100mV below GND or
above VDD. When applying noisy clock signals, especially
sharp edged signals from a long cable during evaluation,
terminate the cable at its characteristic impedance and add
an RC filter to the SYNC pin, if necessary, to soften the slew
rate and over/undershoot. Note that sharp edged signals
from a pulse or function generator can develop under/
overshoot as high as 10V at the end of an improperly terminated cable.
FIGURE 7.
PFM OPERATION
Connecting the SYNC/MODE to SGND sets the LM2619 to
hysteretic PFM operation. While in PFM (Pulse Frequency
Modulation) mode, the output voltage is regulated by switching with a discrete energy per cycle and then modulating the
cycle rate, or frequency, to control power to the load. This is
done by using an error comparator to sense the output
voltage. The device waits as the load discharges the output
filter capacitor, until the output voltage drops below the lower
threshold of the PFM error-comparator. Then the device
initiates a cycle by turning on the PFET switch. This allows
current to flow from the input, through the inductor to the
output, charging the output filter capacitor. The PFET is
turned off when the output voltage rises above the regulation
threshold of the PFM error comparator. Thus, the output
voltage ripple in PFM mode is proportional to the hysteresis
of the error comparator.
In PFM mode, the device only switches as needed to service
the load. This lowers current consumption by reducing power
consumed during the switching action in the circuit, due to
transition losses in the internal MOSFETs, gate drive currents, eddy current losses in the inductor, etc. It also improves light-load voltage regulation. During the second half
of the cycle, the intrinsic body diode of the NFET synchronous rectifier conducts until the inductor current ramps to
zero.
OVERVOLTAGE PROTECTION
The LM2619 has an over-voltage comparator that prevents
the output voltage from rising too high when the device is left
in PWM mode under low-load conditions. When the output
voltage rises by about 100mV (Figure 3) over its regulation
threshold, the OVP comparator inhibits PWM operation to
skip pulses until the output voltage returns to the regulation
threshold. When resistor dividers are used the OVP threshold at the output will be the value of the threshold at the
feedback pin times the resistor divider ratio. In over voltage
protection, output voltage and ripple will increase.
OPERATING MODE SELECTION
The LM2619 is designed for digital control of the operating
modes by the system controller. This prevents the spurious
switch over from low-noise PWM mode between transmission intervals in mobile phone applications that can occur in
other products.
The SYNC/MODE digital input pin is used to select the
operating mode. Setting SYNC/MODE high (above 1.3V)
selects 600kHz current-mode PWM operation. PWM mode
is optimized for low-noise, high-power operation for use
when the load is active. Setting SYNC/MODE low (below
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SHUTDOWN MODE
Setting the EN digital input pin low ( < 0.4V) places the
LM2619 in a 0.02µA (typ) shutdown mode. During shutdown,
the PFET switch, NFET synchronous rectifier, reference,
control and bias circuitry of the LM2619 are turned off.
Setting EN high enables normal operation. While turning on,
soft start is activated.
EN should be set low to turn off the LM2619 during system
power-up and undervoltage conditions when the supply is
10
LM2619
Device Information
(Continued)
Load Transient Response
(Circuit in Figure 3)
less than the 2.8V minimum operating voltage. The LM2619
is designed for compact portable applications, such as mobile phones. In such applications, the system controller determines power supply sequencing. Although the LM2619 is
typically well behaved at low input voltages, this is not guaranteed.
INTERNAL SYNCHRONOUS RECTIFICATION
While in PWM mode, the LM2619 uses an internal NFET as
a synchronous rectifier to reduce rectifier forward voltage
drop and associated power loss. Synchronous rectification
provides a significant improvement in efficiency whenever
the output voltage is relatively low compared to the voltage
drop across an ordinary rectifier diode.
The internal NFET synchronous rectifier is turned on during
the inductor current down slope during the second part of
each cycle. The synchronous rectifier is turned off prior to the
next cycle, or when the inductor current ramps to zero at light
loads. The NFET is designed to conduct through its intrinsic
body diode during transient intervals before it turns on, eliminating the need for an external diode.
20057427
FIGURE 8.
Line Transient Response
(Circuit in Figure 3)
CURRENT LIMITING
A current limit feature allows the LM2619 to protect itself and
external components during overload conditions. In PWM
mode cycle-by-cycle current limit is normally used. If an
excessive load pulls the voltage at the feedback pin down to
approximately 0.7V, then the device switches to a timed
current limit mode. In timed current limit mode the internal
P-FET switch is turned off after the current comparator trips
and the beginning of the next cycle is inhibited for 2.5µs to
force the instantaneous inductor current to ramp down to a
safe value. Timed current limit mode prevents the loss of
current control seen in some products when the voltage at
the feedback pin is pulled low in serious overload conditions.
DROPOUT CONSIDERATIONS
The LM2619 can be used to provide fixed output voltages by
using external feedback resistors. The output voltage can be
set from 1.5V to 3.6V. The internal reference voltage for the
error amplifier is 1.5V. In cases where the output voltage is
set higher than 2.5V, the part will go into dropout or 100%
duty cycle when the input voltage gets close to the set output
voltage. Near dropout the on time of the P-FET may exceed
one PWM clock cycle and cause higher ripple on the output
for load currents greater than 450mA. This increased ripple
will exist for a narrow range of input voltages close to the
100% duty cycle and once the input voltage goes down
further the P-FET will be fully on. See Setting the Output
Voltage in the Application Information section for further
details.
In dropout conditions the output voltage is VIN − IOUT (Rdc +
RDSON (P)) where Rdc is the series resistance of the inductor
and RDSON (P) is the on resistance of the PFET.
20057428
FIGURE 9.
SOFT-START
The LM2619 has soft start to reduce current inrush during
power-up and startup. This reduces stress on the LM2619
and external components. It also reduces startup transients
on the power source. Soft start is implemented by ramping
up the reference input to the error amplifier of the LM2619 to
gradually increase the output voltage.
THERMAL SHUTDOWN PROTECTION
The LM2619 has a thermal shutdown protection function to
protect itself from short-term misuse and overload conditions. When the junction temperature exceeds 150˚C the
device turns off the output stage and when the temperature
drops below 130˚C it initiates a soft start cycle. Prolonged
operation in thermal shutdown conditions may damage the
device and is considered bad practice.
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LM2619
starting value for R3. This value can then be optimized on
the bench to give the best transient response to load
changes, under all conditions. Typical values are 10pF for
C5, 220pF to 1nF for C4 and 22K to 100K for R3.
AO = 20000 , Open loop gain of error amplifier
Rf = 1 , Transresistance of output stage
Mc = 362000 A/s , Corrective ramp slope
Application Information
SETTING THE OUTPUT VOLTAGE
The LM2619 can be used with external feedback resistors to
set the output voltage.Select the value of R2 to allow atleast
100 times the feedback pin bias current to flow through it.
VOUT= VFB (1+R1/R2)
D = VOUT/VIN , D’ = 1-D , duty cycle
M1 = (VIN - VOUT)/L1 , slope of current through inductor
during PFET on time
Rp = (R1 i R2) + 5kΩ , effective resistance at inverting input
of error amp
Ro = (F • L1) / (D’ • (Mc/M1)+ 1⁄2 - D)
where Ro is the effective small signal output resistance of
power stage
fP1 = 1/(2 • π • AO • Rp • C4) , low frequency pole
EXTERNAL COMPENSATION
The LM2619 uses external components connected to the
EANEG and EAOUT pins to compensate the regulator (Figure 4). Typically, all that is required is a series connection of
one capacitor (C4) and one resistor (R3). A capacitor (C5)
can be connected across the EANEG and EAOUT pins to
improve the noise immunity of the loop. C5 reacts with R3 to
give a high frequency pole. C4 reacts with the high open loop
gain of the error amplifier and the resistance at the EANEG
pin to create the dominant pole for the system, while R3 and
C4 react to create a zero in the frequency response. The
pole rolls off the loop gain, to give a bandwidth somewhere
between 10kHz and 50kHz, this avoids a 100kHz parasitic
pole contributed by the current mode controller. Typical values in the 220pF to 1nF (C4) range are recommended to
create a pole on the order of 10Hz or less.
The next dominant pole in the system is formed by the output
capacitance (C2) and the parallel combination of the load
resistance and the effective output resistance of the regulator. This combined resistance (Ro) is dominated by the small
signal output resistance, which is typically in the range of 3Ω
to 15Ω. The exact value of this resistance, and therefore this
load pole depends on the steady state duty cycle and the
internal ramp value. Ideally we want the zero formed by R3
and C4 to cancel this load pole, such that R3=RoC2/C4. Due
to the large variation in Ro, this ideal case can only be
achieved at one operating condition. Therefore a compromise of about 5Ω for Ro should be used to determine a
fP2 = 1/( 2 • π • (Rload i Ro) • C2) , pole due to Rload,Ro and
C2
fP3 = Ro/ (2 • π • L1) , high frequency pole from current mode
control
fP4 = 1/(2 • π • R3 • C5) , high frequency pole due to R3 and
C5
fZ1 = 1/(2 • π • R3 • C4) , zero due to R3 and C4
α = R2/(R1+ R2)
fX = (α • (Ro i Rload)/Rf)/(2 • π • Rp • C4)
where fX gives the approximate crossover frequency.This
equation for crossover frequency assumes that fP2 = fZ1.
INDUCTOR SELECTION
Use a 10µH inductor with saturation current rating higher
than the peak current rating of the device. The inductor’s
resistance should be less than 0.3Ω for good efficiency.
Table 1 lists suggested inductors and suppliers.
TABLE 1. Suggested Inductors and Their Suppliers
Phone
FAX
DO1608C-103
Part Number
Coilcraft
Vendor
847-639-6400
847-639-1469
ELL6SH100M
Panasonic
714-373-7366
714-373-7323
ELL6RH100M
Panasonic
714-373-7366
714-373-7323
CDRH5D18-100
Sumida
847-956-0666
847-956-0702
P0770.103T
Pulse
858-674-8100
858-674-8262
For low-cost applications, an unshielded inductor is suggested. For noise critical applications, a toroidal or shielded
inductor should be used. A good practice is to lay out the
board with footprints accommodating both types for design
flexibility. This allows substitution of a low-noise shielded
inductor, in the event that noise from low-cost unshielded
models is unacceptable.
The saturation current rating is the current level beyond
which an inductor loses its inductance. Different manufacturers specify the saturation current rating differently. Some
specify saturation current point to be when inductor value
falls 30% from its original value, others specify 10%. It is
always better to look at the inductance versus current curve
and make sure the inductor value doesn’t fall below 30% at
the peak current rating of the LM2619. Beyond this rating,
the inductor loses its ability to limit current through the PWM
switch to a ramp. This can cause poor efficiency, regulation
errors or stress to DC-DC converters like the LM2619. Saturation occurs when the magnetic flux density from current
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through the windings of the inductor exceeds what the inductor’s core material can support with a corresponding
magnetic field.
CAPACITOR SELECTION
Use a 10µF ceramic input capacitor. Use X7R or X5R types,
do not use Y5V.
Use of tantalum capacitors is not recommended.
Ceramic capacitors provide an optimal balance between
small size, cost, reliability and performance for cell phones
and similar applications. A 22µF ceramic output capacitor is
recomended for applications that require increased tolerance to heavy load transients. A 10µF ceramic output capacitor can be used in applications where the worst case
load transient step is less than 200mA. Use of a 10µF output
capacitor trades off smaller size for an increase in output
voltage ripple, and undershoot during load transients. Table
2 lists suggested capacitors and suppliers.
12
transient load changes and reduces output voltage ripple.
These capacitors must be selected with sufficient capacitance and sufficiently low ESR to perform these functions.
(Continued)
The input filter capacitor supplies current to the PFET switch
of the LM2619 in the first part of each cycle and reduces
voltage ripple imposed on the input power source. The output filter capacitor smoothes out current flow from the inductor to the load, helps maintain a steady output voltage during
The ESR, or equivalent series resistance, of the filter capacitors is a major factor in voltage ripple.
TABLE 2. Suggested Capacitors and Their Suppliers
Model
Type
Vendor
Phone
FAX
C1, C2 (Input or Output Filter Capacitor)
C2012X5ROJ106M
Ceramic
TDK
847-803-6100
847-803-6296
JMK212BJ106MG
Ceramic
Taiyo-Yuden
847-925-0888
847-925-0899
ECJ3YB0J106K
Ceramic
Panasonic
714-373-7366
714-373-7323
JMK325BJ226MM
Ceramic
Taiyo-Yuden
847-925-0888
847-925-0899
C3225X5RIA226M
Ceramic
TDK
847-803-6100
847-803-6296
MICRO SMD PACKAGE ASSEMBLY AND USE
Good layout for the LM2619 can be implemented by following a few simple design rules.
Use of the micro SMD package requires specialized board
layout, precision mounting and careful reflow techniques, as
detailed in National Semiconductor Application Note AN1112. Refer to the section Surface Mount Technology (SMT)
Assembly Considerations. For best results in assembly,
alignment ordinals on the PC board should be used to
facilitate placement of the device.
The pad style used with micro SMD package must be the
NSMD (non-solder mask defined) type. This means that the
solder-mask opening is larger than the pad size. This prevents a lip that otherwise forms if the solder-mask and pad
overlap, from holding the device off the surface of the board
and interfering with mounting. See Application Note AN-1112
for specific instructions how to do this.
The 10-Bump package used for the LM2619 has 300 micron
solder balls and requires 10.82mil pads for mounting on the
circuit board. The trace to each pad should enter the pad
with a 90˚ entry angle to prevent debris from being caught in
deep corners. Initially, the trace to each pad should be
6–7mil wide, for a section approximately 6mil long, as a
thermal relief. Then each trace should neck up or down to its
optimal width. The important criterion is symmetry. This ensures the solder bumps on the LM2619 reflow evenly and
that the device solders level to the board. In particular,
special attention must be paid to the pads for bumps D3–B3.
Because PGND and PVIN are typically connected to large
copper planes, inadequate thermal reliefs can result in late
or inadequate reflow of these bumps.
The micro SMD package is optimized for the smallest possible size in applications with red or infrared opaque cases.
Because the micro SMD package lacks the plastic encapsulation characteristic of larger devices, it is vulnerable to light.
Backside metalization and/or epoxy coating, along with frontside shading by the printed circuit board, reduce this sensitivity.
1.
2.
3.
4.
5.
BOARD LAYOUT CONSIDERATIONS
PC board layout is an important part of DC-DC converter
design. Poor board layout can disrupt the performance of a
DC-DC converter and surrounding circuitry by contributing to
EMI, ground bounce, and resistive voltage loss in the traces.
These can send erroneous signals to the DC-DC converter
IC, resulting in poor regulation or instability. Poor layout can
also result in reflow problems leading to poor solder joints
between the micro SMD package and board pads. Poor
solder joints can result in erratic or degraded performance.
6.
13
Place the LM2619 on 10.82 mil (10.82/1000 in.) pads.
As a thermal relief, connect to each pad with a 7 mil
wide, approximately 7 mil long traces, and then incrementally increase each trace to its optimal width. The
important criterion is symmetry to ensure the solder
bumps on the LM2619 reflow evenly (see micro SMD
Package Assembly and Use).
Place the LM2619, inductor and filter capacitors close
together and make the traces short. The traces between
these components carry relatively high switching currents and act as antennas. Following this rule reduces
radiated noise. Place the capacitors and inductor within
0.2 in. (5 mm) of the LM2619.
Arrange the components so that the switching current
loops curl in the same direction. During the first half of
each cycle, current flows from the input filter capacitor,
through the LM2619 and inductor to the output filter
capacitor and back through ground, forming a current
loop. In the second half of each cycle, current is pulled
up from ground, through the LM2619 by the inductor, to
the output filter capacitor and then back through ground,
forming a second current loop. Routing these loops so
the current curls in the same direction prevents magnetic field reversal between the two half-cycles and reduces radiated noise.
Connect the ground pins of the LM2619, and filter capacitors together using generous component-side copper fill as a pseudo-ground plane. Then, connect this to
the ground-plane (if one is used) with several vias. This
reduces ground-plane noise by preventing the switching
currents from circulating through the ground plane. It
also reduces ground bounce at the LM2619 by giving it
a low-impedance ground connection.
Use wide traces between the power components and for
power connections to the DC-DC converter circuit. This
reduces voltage errors caused by resistive losses across
the traces.
Route noise sensitive traces, such as the voltage feedback path, away from noisy traces between the power
components. The voltage feedback trace must remain
close to the LM2619 circuit and should be routed directly
from VOUT at the output capacitor and should be routed
opposite to noise components. This reduces EMI radiated onto the DC-DC converter’s own voltage feedback
trace.
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LM2619
Application Information
LM2619
Application Information
arrange the CMOS digital circuitry around it (since this also
generates noise), and then place sensitive preamplifiers and
IF stages on the diagonally opposing corner. Often, the
sensitive circuitry is shielded with a metal pan and power to
it is post-regulated to reduce conducted noise, using lowdropout linear regulators.
(Continued)
7. Place noise sensitive circuitry, such as radio IF blocks,
away from the DC-DC converter, CMOS digital blocks
and other noisy circuitry. Interference with noisesensitive circuitry in the system can be reduced through
distance.
In mobile phones, for example, a common practice is to
place the DC-DC converter on one corner of the board,
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14
inches (millimeters) unless otherwise noted
NOTES: UNLESS OTHERWISE SPECIFIED
1. EPOXY COATING
2. 63Sn/37Pb EUTECTIC BUMP
3. RECOMMEND NON-SOLDER MASK DEFINED LANDING PAD.
4. PIN A1 IS ESTABLISHED BY LOWER LEFT CORNER WITH RESPECT TO TEXT ORIENTATION.
5. XXX IN DRAWING NUMBER REPRESENTS PACKAGE SIZE VARIATION WHERE X1 IS PACKAGE WIDTH, X2 IS PACKAGE LENGTH AND X3 IS
PACKAGE HEIGHT.
6. REFERENCE JEDEC REGISTRATION MO-211. VARIATION BD.
10-Bump micro SMD Package
NS Package Number TLP106WA
The dimensions for X1, X2 and X3 are as given:
X1 = 2.250 ± 0.030 mm
X2 = 2.504 ± 0.030 mm
X3 = 0.600 ± 0.075 mm
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LM2619 500mA Sub-Miniature Step-Down DC-DC Converter
Physical Dimensions