DIODES ZXLB1600X10TC

ZXLB1600
LCD AND OLED BIAS BOOST CONVERTER - STN, CSTN SCREENS
DESCRIPTION
FEATURES
• Wide input voltage range: 1.6 to 5.5V
• Adjustable output voltage up to 28V, using PWM
The ZXLB1600 inductive switching boost converter
accepts an input voltage of between 1.6V and 5.5V and
provides an adjustable output voltage of up to 28V for
LCD and OLED bias. The device contains an output
switch and a second switch to isolate the coil from the
input to provide true isolation in shutdown mode. The
output can be adjusted by means of an externally
applied dc voltage, a PWM control signal, or external
feedback resistors and can supply typically 10mA of
output current at maximum output voltage. Higher
current is available at lower output voltages.
or analog control voltage
The input voltage range accepts a number of battery
solutions, including dual dry cell and single Li-Ion cells
and PFM operation mode allows the output to be
regulated with high efficiency under light or no load
conditions. The switching frequency range permits the
use of miniature surface mount inductors.
•
•
•
•
•
Internal PWM filter
•
•
•
•
Up to 500kHz switching frequency
True shutdown (output isolated from input)
Internal output switch and current sense
Low quiescent current: (75␮A max)
5␮A (max) shutdown current (including low
battery comparator)
High efficiency
Small MSOP10 package
Low external component count
APPLICATIONS
•
•
•
•
•
A low battery comparator is provided to indicate when
the input voltage has fallen to within ±2% of a preset
threshold. This threshold is set internally , but can be
adjusted externally to any voltage within the supply
voltage range.
PDAs
Mobile phones - OLED sub displays
Digital cameras
Portable internet appliances
Palmtop computers
• GPS terminals
TYPICAL APPLICATION CIRCUIT
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SEMICONDUCTORS
ZXLB1600
ABSOLUTE MAXIMUM RATINGS
(Voltages to GND unless otherwise stated)
Output voltage
Input voltage
Switch output current
Power dissipation
Operating temperature
Storage temperature
Junction temperature
30V
7V
500mA
800mW
0 to 70⬚C
-55 to 125⬚C
150⬚C
ELECTRICAL CHARACTERISTICS
Test conditions unless otherwise stated: VIN = 3.0V, TAMB = 25°C
Symbol
Parameter
Conditions
Min
Typ
Max
Units
General
V IN
I IN
Input voltage (1)
Supply current Shutdown
1.6
(2)
Quiescent
5.5
V
V EN = 0V
3.5
5
␮A
V EN = V IN , I OUT = 0V, Not
switching
30
75
␮A
V EN = V IN
V EN = 0V
0.7
2
⍀
1
␮A
Isolating switch
R ISO
‘On’ resistance
I ISO
Leakage current
V SW(max)
Maximum voltage on SW pin
during normal operation
VIN+0.5 V
LX Switch
I LX
Switch peak current limit (3)
R LX
‘On’ resistance
I LX(leak)
Switch leakage current
V LX
Operating voltage on LX pin
0.15
0.35
A
2
⍀
1
␮A
-0.5
30
V
VIN
28
V
0.5
Controller output
V OUT
Output voltage range
I OUT
Output current
Lx = 22␮H, V OUT = 28V
10
mA
⌬V LNR
Line regulation
I OUT = 1mA, 2V < V IN <5.5V
0.1
%/V
⌬V LDR
Load regulation
V OUT = 28V, 100␮A < I OUT
< 5mA
0.15
%/mA
f LX
Operating frequency
T ON
Output ‘ON’ time
LX output low
T OFF
Output ‘OFF’ time
LX output off
␩
Efficiency (4)
Lx = 22␮H, V OUT = 20V
5
0.9
500
kHz
10
␮s
µs
80
%
Note:
1) Minimum supply voltage should be maintained above 2V for operation at minimum temperature.
2) Shutdown current includes the operating current for the low battery comparator, which remains active in shutdown mode.
3) This is the dc value. The dynamic value may exceed 350mA during normal operation, due to switching delays, coil inductance and supply
voltage.
4) Efficiency is dependent upon the choice of external components, input/output voltages and load current.(see typical operating curves).
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ZXLB1600
ELECTRICAL CHARACTERISTICS (Cont.)
Test conditions unless otherwise stated: VIN = 3.0V, TAMB = 25°C
Symbol
Parameter
Conditions
Min Typ
Max
Units
Output voltage control by dc voltage applied to ‘ADJ’ pin
V ADJ (nom)
Internal reference voltage
V ADJ
Temperature coefficient of V ADJ
External overdrive voltage range
on ‘ADJ’ pin for output voltage
control
I ADJ
Input current into V ADJ pin
V SENSE
Default Output voltage
∆T/T
PWM duty cycle range at ‘EN’
input
f LPF
Internal low pass filter cut-off
frequency
A LPF
Filter attenuation
‘ADJ’ pin floating, ‘EN’= V IN
1.23
V
40
0.5
0.5<V ADJ < V ADJ (NOM)
‘ADJ’ pin floating, ‘EN’= V IN
Output voltage control by PWM signal applied to ‘EN’ input
10kHz(5) < f < 100kHz, VENH =VIN
ppm/⬚C
VADJ
(NOM)
V
-10
␮A
27
29
V
40
100
%
f=30kHz
4
kHz
52.5
dB
Internal voltage setting resistors for output voltage
R1
Ref. Block diagram
R2
317
k⍀
6.93
M⍀
Enable input
V ENL
Low level Input voltage
Device in shutdown
V ENH
High level Input voltage
Device active
I ENL
Low level input current
V EN =0V
I ENH
High level input current
V EN =V IN
T EN(hold)
Enable active hold time (6)
V EN switched from high to low
0.4
1.4
V
Vin
V
-100
nA
100
nA
␮s
120
Low-battery detection circuit
V LBT
Detection threshold
V IN falling
Temperature coefficient of V BLT
1.94
2.02
20
V IN rising
V
ppm/⬚C
V BLHYS
Hysteresis
Ref (LBD)
V LBT (max)
Internal reference voltage
20
mV
I BLOL
Low level output current
Output ‘on’
V BLOL
Low level output voltage
I BLOL = 0.5mA
0.4
I BLOH
High level output current
␮A
High level output voltage
Output ‘off’ , V BLOH = 29V
Output ‘off’
2
V BLOH
29
V
1.21
Maximum voltage on LBT pin
V
Vin-0.5 V
1
mA
V
Internal voltage setting resistors for low-battery detection circuit
R3
Ref. block diagram
R4
1.56
M⍀
2.44
M⍀
Note:
5)
6)
This is the minimum PWM frequency to maintain a continuous output. Lower frequencies can be used, but will result in gated operation of
the device i.e. device enters shutdown when EN is low (see Note 6).
This is the time for which the device remains active after the EN pin has been driven low. This delay allows a continuous output to be
maintained during PWM mode operation at frequencies higher than 10kHz.
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SEMICONDUCTORS
ZXLB1600
PIN CONNECTIONS
PIN DESCRIPTION
Pin #
Name
Description
1
ADJ
Internal (or external) reference voltage.
2
EN
Can be overdriven to adjust output voltage
Enable input (active high)
Also used to adjust output voltage by PWM signal
3
VIN
Input voltage
4
SW
Output of high side PMOS isolation switch
5
SENSE
Output voltage sense
6
LX
Output of NMOS switch
7
LBF
Low battery flag output: open drain
(active low for low battery voltage)
Active when EN is high or low
8
GND
Ground
9
FB
Voltage feedback pin for output (threshold 1.23V)
10
LBT
Low battery flag threshold adjust input
(threshold 1.21V)
ORDERING INFORMATION
DEVICE
DEVICE DESCRIPTION
TEMPERATURE
RANGE
PART MARK
ZXLB1600X10TA
Boost converter for LCD bias in MSOP10
0 ⬚C to 70 ⬚C
ZXLB1600
ZXLB1600X10TC
Boost converter for LCD bias in MSOP10
0 ⬚C to 70 ⬚C
ZXLB1600
TA reels 1k,
TC reels 4k devices.
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ZXLB1600
BLOCK DIAGRAM
Device description
Setting output voltage
The device is a flyback boost converter, working in
discontinuous mode.
With external voltage
The output voltage is equal to the voltage present on
the 'ADJ' pin of the device multiplied by the internal
resistor network factor (R1+R2)/R1. The ADJ pin is
connected to the internal reference voltage of value
VADJ(nom) and by default will give a nominal output of
28V. However, if required, the ADJ pin may be
overdriven with an external dc voltage VADJ, in order to
adjust the output voltage to a value lower than the
default value.
With reference to the chip block diagram and typical
application circuit, the operation of the device is as
follows:
Control loop
When 'EN' is high, the control circuits become active. The
high side of the coil is connected to the input via a large
PMOS isolating switch (MP) and the low side to ground via
NDMOS transistor (MN). The current in the coil is allowed
to build up to an internally defined level (nominally 200 to
300mA) before MN is turned off. The energy stored in the
coil is then transferred to the output capacitor (C2) via
diode (D1). The output voltage is sensed at pin 'SENSE' by
internal resistors R1 and R2 (which may be shunted
externally at pin 'FB') and compared to a reference voltage
(1.23V nominal). A comparator senses when the output
voltage is above that set by the reference and its output is
used to control the 'off' time of the output switch. The
control loop is self-oscillating, producing pulses of 10␮s
maximum duration (switch 'on'), at a frequency that varies
in proportion to the output load current. The minimum
'off' time of the output switch is fixed at 1.25␮s nominal, to
allow time for the coil's energy to be dissipated before the
switch is turned on again. This maintains stable and
efficient operation.
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SEMICONDUCTORS
ZXLB1600
Filtered PWM operation
Low battery detection
The input of an internal low pass filter is switched to
VREF when the EN pin is high and switched to ground
when the EN pin is low. The output of this filter drives
the comparator within the control loop. A continuous
high state on EN therefore provides a filtered voltage of
value Vref to the comparator and the control loop
regulates the output to a nominal value of 28V.
However, by varying the duty cycle (D) of the EN signal
at a suitably high frequency (f>10kHz), the control loop
will see a voltage, that has an average value equal to
the duty cycle multiplied by VREF. This provides a
means of adjusting the output voltage to a lower value.
It also allows the device to be both turned on and
adjusted with a single signal at the 'EN' pin. The output
during this mode of operation will be a dc voltage equal
to D x 28V
A comparator driving an open drain NMOS output
transistor performs the low battery flag function. The
detection threshold (battery voltage falling) is set to
1.98V nominal with internal resistors R3 and R4, but
this can be changed by shunting the internal potential
divider with two external resistors at pin 'LBT'.
Operation is such that the output transistor will be
turned on when the battery voltage falls below the
detection threshold.
VBLT = 1.21 x (R3+R4)/R4
A small amount (nominal 20mV) of hysteresis is
provided to aid clean switching. The low battery
detection circuit remains active when 'EN' is low.
Gated PWM operation
The internal circuitry of the ZXLB1600 is turned off
when no signal is present on the 'EN' pin for more than
120␮s (nominal). A low frequency signal applied to the
EN pin will therefore gate the device 'on' and 'off' at the
gating frequency and the duty cycle of this signal can
be varied to provide a 'chopped' output voltage equal
to D x 28V. For best accuracy, the gating frequency
should be made as low as possible (e.g. below 1kHz),
such that the turn off delay of the chip is only a small
proportion of the gating period.
Further details of setting output current are given in the
application notes.
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ZXLB1600
TYPICAL OPERATING CHARACTERISTICS
(For typical applications circuit at Vin = 3V and TA = 25⬚C unless otherwise stated)
Plot 1 Start-up response at max output voltage 1mA load
Bottom: Enable input (1V/div), Top: Output voltage (10V/div)
Plot 2 Start-up response at max output voltage 5mA load
Bottom: Enable input (1V/div), Top: Output voltage (10V/div)
Plot 3 Operating waveforms at max output voltage 1mA load
Bottom: LX Output (10V/div), Top: Output voltage (50mV/div ac)
Plot 4 Operating waveforms at max output voltage 10mA load
Bottom: LX Output (10V/div), Top: Output voltage (50mV/div ac)
Plot 5 Line rejection at 1mA load
Bottom: Input voltage (1V/div), Top: Output voltage (0.2V/div ac)
Plot 6 Load rejection
Bottom: Load current (1mA/div), Top: Output voltage (0.1V/div ac)
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SEMICONDUCTORS
ZXLB1600
TYPICAL OPERATING CHARACTERISTICS (Continued)
VIN = 3V and TA = 25⬚C
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SEMICONDUCTORS
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ZXLB1600
TYPICAL OPERATING CHARACTERISTICS (Continued)
VIN = 3V and TA = 25⬚C
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SEMICONDUCTORS
ZXLB1600
TYPICAL OPERATING CHARACTERISTICS (Continued)
VIN = 3V and TA = 25⬚C
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SEMICONDUCTORS
10
ZXLB1600
APPLICATION NOTES
in this way. However, some non-linearity in the above
expression may occur at values of VADJ below
approximately 0.5V.
Adjusting output voltage
When connected as shown in the typical application
circuit, the ZXLB1600 will produce a nominal output
voltage of 28V. This can be adjusted by one of the three
methods described below.
Also note that when driving the ADJ pin, the control
voltage must have sufficiently low impedance to sink
the bias current of the internal reference.(10␮A max).
1) Output voltage adjustment by external resistors
3) PWM output adjustment
The internal reference and resistor divider network R1
and R2 set a nominal output of 28V. However, this
network is accessible at the FB pin and can be shunted
by means of external resistors to set different nominal
output voltages. The potential divider defines output
voltage according to the relationship:
A Pulse Width Modulated (PWM) signal can be applied
to the EN pin in order to adjust the output voltage to a
value below the value set in in 1) or 2). This method of
adjustment permits the device to be turned on and the
output voltage set by a single logic signal applied to the
EN pin. No external resistors or capacitors are required
and the amplitude of the control signal is not critical,
providing it conforms to the limits defined in the
electrical characteristics.
VOUT(dc) = (R1+R2)/R1 x 1.23V
When using external resistors, these should be chosen
with lower values than the internal resistors to
minimize errors caused by the ±25% absolute value
variation of the internal resistors. The internal resistors
have high values in order to minimize these errors.
Two modes of adjustment are possible as described
below:
Filtered 'DC' mode
The following table gives suggested E24/E96 resistor
values for various output voltages.
Required
output
voltage
External resistor
across R2
External resistor
across R1
5V
280k⍀
91k⍀
12V
715k⍀
82k⍀
18V
1 M⍀
75k⍀
20V
1.15 M⍀
75k⍀
22V
1.15M⍀
68.1k⍀
25V
1.2 M⍀
62k⍀
If a PWM signal of 10kHz or higher is applied to the EN
pin, the device will remain active when the EN pin is
low. However, the input to the internal low pass filter
will be switched alternately from VREF to ground, with a
duty cycle (D) corresponding to that of the PWM signal.
This will present a filtered dc voltage equal to the duty
cycle multiplied by VREF to the control loop and will
produce a dc output voltage lower than the maximum
set value. This voltage is given by:
VOUT = 28 x D
A square wave signal applied to the EN pin, for
example, will turn the device on and produce a nominal
regulated output of 14V.
2) Output adjustment by external voltage
The internal voltage reference (Pin ADJ) may be
overdriven by an external control voltage to set the
output voltage. The relationship between applied
voltage (VADJ) and output voltage (VOUT) is:
VOUT = 22.86 x VADJ
Note that the output can be set to any value between
the input voltage and the maximum operating voltage
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SEMICONDUCTORS
ZXLB1600
C2 have relatively low values in this circuit in order to
give a short time constant. This improves the
regulation of the negative voltage.
Gated mode
The ZXLB1600 contains a timing circuit that switches
the device on a few microseconds after the application
of a rising edge to EN and turns it back off again
nominally 120␮s after the falling edge of EN. So, if a
lower frequency of 1kHz or less is applied to the EN pin,
the device will be gated on and off at a duty cycle (D)
corresponding to that of the input signal. The average
output voltage is then given by:
Capacitor selection
A low ESR ceramic capacitor grounded close to the
GND pin of the package is recommended at the output
of the device. Surface mount types offer the best
performance due to their lower inductance. A
minimum value of 1␮F is advised, although higher
values will lower switching frequency and improve
efficiency especially at lower load currents. A higher
value will also minimize ripple when using the device
to provide an adjustable dc output voltage.
VOUT(avg) ~ 28 x D
Output voltage can be adjusted all the way down to the
input voltage by means of PWM control, but for best
results, the duty cycle range should be kept within the
specified range of 0.4 to 1. Lower duty cycles may
result in increased output ripple and non-linearity in
the relationship between duty cycle and output
voltage. If a greater control range, or reduced ripple is
required, the nominal output can be adjusted by one of
the other methods before the PWM signal is applied.
A good quality, low ESR capacitor should also be used for
input decoupling, as the ESR of this capacitor is effectively
in series with the source impedance and lowers overall
efficiency. This capacitor has to supply the relatively high
peak current to the coil and smooth the current ripple on
the input supply. A minimum value of 3.3␮F is acceptable
if the input source is close to the device, but higher values
are recommended at lower input voltages, when the
source impedance is high. The input capacitor should be
mounted as close as possible to the IC.
Negative output
The ZXLB1600 can be used to provide a negative
output voltage (in addition to the normal positive
output) as shown in the application circuit below. In
this circuit, the external resistors R3 an R4 are used to
set the output voltage to 22V as described in the
previous section. These resistors and output capacitor
For maximum stability over temperature, capacitors
with X7R dielectric are recommended, as these have a
much smaller temperature coefficient than other types.
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SEMICONDUCTORS
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ZXLB1600
Inductor selection
Diode selection
The choice of inductor will depend on available board
space as well as required performance. Small value
inductors have the advantage of smaller physical size
and may offer lower series resistance and higher
saturation current compared to larger values. A
disadvantage of smaller inductors is that they result in
higher frequency switching, which in turn causes
reduced efficiency due to switch losses. Higher
inductor values can provide better performance at
lower supply voltages. However, if the inductance is
too high, the output power will be limited by the
internal oscillator, which will prevent the coil current
from reaching its peak value. This condition will arise
whenever the ramp time ILX(peak) x L/VIN exceeds the
preset 10µs maximum ‘on’ time limit for the LX output.
The rectifier diode (D1) should be a fast low
capacitance switching type with low reverse leakage at
the working voltage. It should also have a peak current
rating above the peak coil current and a continuous
current rating higher than the maximum output load
current. Small schottky diodes such as the BAT54 are
suitable for use with the ZXLB1600 and this diode will
give good all round performance over the output
voltage and current range. At lower output voltages, a
larger schottky diode such as the ZHCS500 or MBR0540
will provide a smaller forward drop and higher
efficiency. At higher output voltages, where forward
drop is less important, a silicon switching diode such
as the 1N4148 can be used, however this will give lower
efficiency.
The ZXLB1600 has been optimized for use with
inductor values in the range 10␮H to 100␮H. The typical
characteristics show how efficiency and available
output current vary with input voltage and inductance.
The inductor should be mounted as close to the device
as possible with low resistance connections to the LX
and SW pins.
The BAT54S device specified in the application circuit
contains a second diode (D2) as one half of a series
connected pair. This second diode is used here to
clamp possible negative excursions (due to coil
ringing) from driving the drain of the output transistor
below -0.5V. This prevents internal coupling effects,
which might otherwise affect output regulation. The
table below gives some typical characteristics for
various diodes.
Suitable coils for use with the ZXLB1600 are those in
the LP02506 and DO1608 series, made by Coilcraft.
Diode
Forward voltage at 100mA (V)
Peak current
(mA)
Continuous current
(mA)
Reverse leakage (µA)
BAT54
530
300
200
2
ZHCS500
300
1000
500
15
MBR0540
390
1000
500
1
1N4148
950
450
200
0.025
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SEMICONDUCTORS
ZXLB1600
Increased efficiency
Low battery detection circuit
If isolation of the coil from the supply is not needed, the
high side of this can be connected directly to VIN to
improve efficiency. This prevents power loss in the
internal PMOS switch and typical efficiency gains of 5%
can be achieved. (See efficiency vs. load curves). Some
applications may require the coil to be fed from a
separate supply with a different voltage to VIN. In this
case, the SW pin should be left floating.
The device contains an independent Low Battery
Detection Circuit that remains powered when the
device is shutdown. The detection threshold is set
internally to a default value of 1.98V, but can be
adjusted by means of external resistors as described
below.
Low battery threshold adjustment, LBT
The internal potential divider network R3/R4 sets the
detection threshold. This is accessible at the LBT pin
and can be shunted by means of external resistors to
set different nominal threshold voltages. The potential
divider defines threshold voltage according to the
relationship:
Layout considerations
PCB tracks should be kept as short as possible to
minimize ground bounce and the ground pin of the
device should be soldered directly to the ground plane.
It is particularly important to mount the coil and the
input/output capacitors close to the device to minimize
parasitic resistance and inductance, which will
degrade efficiency and increase output ripple. The FB
and LBT pins are high impedance inputs, so PCB track
lengths to these should also be kept as short as
possible to reduce noise pickup. Output ripple is
typically only 50mV p-p, but a small feed-forward
capacitor (~100pF) connected from the FB pin to the
output may help to reduce this further. Capacitance
from the FB pin to ground should be avoided, but a
capacitor can be connected from the LBT pin to ground
to reduce noise pickup into the low battery comparator
if required.
VLBT = (R3+R4)/R4 x 1.21V
When using external resistors, these should be chosen
with lower values than the internal resistors to
minimize errors caused by the ⫾25% absolute value
variation of the internal resistors. The internal resistors
have high values in order to minimize these errors. It is
suggested to use values less than half those shown for
R3, R4 at the bottom of page 3.
Low battery flag output, LBF
This is an open drain output that switches low when the
battery voltage falls below the detection threshold. An
external pull-up resistor can be connected to this pin to
allow it to interface to any voltage up to a maximum of
29V. Current in the pull-up resistor should be limited to
a value below IBLOL.
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SEMICONDUCTORS
14
ZXLB1600
Notes:
ISSUE 3 - SEPTEMBER 2003
15
SEMICONDUCTORS
ZXLB1600
PACKAGE OUTLINE
PACKAGE DIMENSIONS
DIM
MILLIMETER
INCHES
MIN.
MAX.
MIN.
MAX.
A
ᎏ
1.10
ᎏ
0.43
A1
ᎏ
0.15
ᎏ
0.006
A2
0.75
0.95
0.0295
0.037
D
3.00 BSC
0.118 BSC
E
4.90 BSC
0.1929 BSC
E1
3.00 BSC
0.118 BSC
b
0.17
0.27
0.0066
0.0106
c
0.08
0.23
0.003
0.009
e
0.50 BSC
0.0196 BSC
⍜
0⬚
15⬚
0⬚
15⬚
L
0.40
0.80
0.015
0.031
L1
0.95 BSC
0.037 BSC
Controlling dimensions are in millimeters. Approximate conversions are given in inches
© Zetex plc 2003
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SEMICONDUCTORS
16