LINEAR TECHNOLOGY LTC3593 Technical data

L DESIGN IDEAS

CTRL

V

IN

10µH

V

IN

3V TO 5V

LT3593

SHUTDOWN AND

CURRENT CONTROL

C1: TAIYO YUDEN EMK107BJ105MA
C2: MURATA GRM31MR71H105KA88
L1: MURATA LQH43CN100
D1: CENTRAL CMDSH05-4

SW

CAP

LED

GND

1µF 1µF

LED CURRENT (mA)

0

EFFI CIENCY (%)

90

70

50

80

60

40

30

10 20155

VIN = 3.6V
10 LEDs

CTRL

LED

CURRENT

128µs

20mA 20mA

17.5mA 17.5mA

SHDN

128µs 128µs

LED

V

IN

L1

10µH

V

IN

3V TO 5V

LT3593

SW

CAP

CTRL

GND

C2
1µF

D1

C1
1µF

SHUTDOWN AND

CURRENT CONTROL

C1: TAIYO YUDEN EMK107BJ105MA
C2: TAIYO YUDEN GMK316BJ105ML
L1: MURATA LQH43CN100
D1: CENTRAL CMDSH05-4

White LED Driver with Output
Disconnect and 1-Wire
Current Programming

Introduction

The LT3593 is designed to drive up to
ten white LEDs in series from a single
lithium-ion cell, ensuring matched
LED current and eliminating the need
for ballast resistors. The LT3593 in­ternally compensated step-up DC/DC
converter switches at 1MHz so that
it can be used with tiny, low profile
external components.

The LT3593 features an internal
5-bit DAC, allowing the LED current
to be programmed using only one
pin. The device features true output
disconnect in shutdown as well as a
unique high side current sense allow­ing it to function as a “1-wire” current
source where the low side of the LEDs
can be returned to ground anywhere.
A typical application schematic along
with expected efficiency can be seen
in Figure 1. The functionality and
feature set available in the LT3593
make it ideal for portable electronics
display back-lighting applications.

The LT3593 is available in a 6-lead
(2mm × 2mm) DFN as well as 6-lead
SOT-23.

1-Wire Current Programming

The LED current can be programmed
linearly to 32 unique values by strobing
the CTRL pin. A 5-bit internal counter
is decremented on each rising edge
on the CTRL pin, reducing the pro­grammed current by 625µA from the
full-scale current of 20mA with each
step. The programmed LED current
can be calculated using the following
equation:

I

= 20mA – (N – 1) • 625µA

LED

where N is the number of rising edges
on the CTRL pin. Strobing the CTRL
pin more than 32 times results in
the minimum current of 625µA. The
CTRL pin must stay high after the last
CTRL strobe and 128µs later the part
will turn on and start to regulate the

by Ahmed Hashim

programmed current. To shut down
the part, the CTRL pin is held low;
128µs after the falling edge of CTRL,
the part shuts down. Figure 2 shows
current programming and shutdown
timing.

If the LED current needs to be
reprogrammed, there is no need to
shutdown and then reprogram. The
LT3593 can be reprogrammed from
one LED current to another by simply
strobing the CTRL pin and, 128µs after
the last rising edge, the part starts
regulating the newly programmed
current (also shown in Figure 2).

Buck-Boost Mode

If a low number of LEDs is needed,
there could be a case where the re­quired output voltage is lower than the
input voltage. In this case, the LT3593
can be used in buck-boost mode where
the LED string is returned to the input
supply instead of ground. Figure 3

36

36

Figure 1. LED driver for ten white LEDs

Figure 2. Current programming and shutdown timing

Figure 3. LED driver in Buck-Boost
mode driving one LED

Linear Technology Magazine • June 2008

DESIGN IDEAS L

V

CAP

20V/DIV

400µs/DIVVIN = 3.6V
FIGURE 1
APPLICATION CIRCUIT

I

L

200mA/DIV

V

SW

20V/DIV

LEDs DISCONNECTED
AT THIS INSTANT

1ms/DIV

V

CORE

, 1V/DIV

V

BST

, 1V/DIV

V

I/O

, 1V/DIV

SWBST V

INBKVBST

LTC3100

FBBST

3.3µH

3.5V

1M

523k

10µF

C

IN

2.2µF

V

LDO

V

INBST

FBLDO

SWBK

PGBK

PGBST

115k

25.5k

V

BATT

0.9V TO 1.5V

2.2µF

FBBK

1M

1M

10µF

MODE

RUNBST

RUNLDO

RUNBK GND

FF EN_BURST

OFF ON

3.3µH

3.3V AT 50mA

V_I/O

120mA AT V

BATT

= 0.9V

220mA AT V

BATT

= 1.2V

V_CORE = 1.2V

BOOST_GOOD

BUCK_GOOD

1M 1M

+

shows an application where a single
LED is driven from a 5V supply.

Output Disconnect

The LT3593 has an internal disconnect
switch that is used to sense the LED
current during normal operation. This
internal switch also serves to provide
output disconnect during shutdown so
that the LEDs are truly disconnected
from the output of the regulator.

Fault Protection

The LT3593 protects against both
open and shorted LED faults. In the
case of an open LED fault, the output
voltage V
V

reaches 38V, an open fault is

CAP

triggered and the part goes into a low
frequency mode clamping the output
to 38V and minimizing input current.

LTC3100, continued from page 32

power while maximizing battery life.
The diode on the USB input prevents
any reverse current from the 3.3V
output (while operating on batter­ies) back to the USB input when it is
open or grounded. Figure 2 shows the
converter efficiency versus load with
various input sources, illustrating the
high efficiency over a wide load range.
The LDO in the LTC3100 (with its input
internally tied to the Boost output)
provides a second regulated output,
in this case programmed to 1.8V.

continues to rise. Once

CAP

A waveform showing the LT3593’s
response to an open LED fault can be
seen in Figure 4.

In a shorted LED fault, the LED pin
can be shorted to ground, running
excessive current from V

. To protect

CAP

from such a fault, the LT3593 limits
the maximum current out of the LED
pin to approximately 45mA.

Conclusion

The LT3593 is a step-up LED driver
that can drive up to ten white LEDs
from a single lithium-ion cell. It can
easily be programmed through a single
pin interface and combines many
desirable features as well as fault
protection against open or shorted
LEDs.

The feature-rich LT3593 is available
in the 6-lead (2mm × 2mm) DFN as

Because the buck converter input
can come from the boost output, the
LTC3100 can function as an ultra-low
voltage buck-boost converter, provid­ing a regulated 1.2V output from a
single alkaline or NiMH cell. This is
shown in Figure 3, where the LTC3100
generates two regulated outputs from
a single cell input (whose voltage may
be above or below 1.2V) by boosting VIN
up to 3.5V and then regulating down
to 1.2V and 3.3V using the buck and
the LDO. In this example, the Power
Good outputs and the LDO are used

well as the 6-lead SOT-23. These two
small, low profile packages, together
with internal compensation and an
output disconnect device, are ideal
for a complete small board area LED
driver solution, especially in portable
device display backlighting applica­tions.

L

Figure 4. Open LED fault protection

to provide voltage sequencing, so that
the 1.2V core supply comes up before
the 3.3V I/O supply, as shown in the
scope photo of Figure 4. The LDO also
provides additional noise filtering and
ripple rejection for the 3.3V output,
guaranteeing a low noise output for
sensitive analog circuitry, even when
the converters are in Burst Mode
operation.

Conclusion

The LTC3100 is a high efficiency, mul­tichannel converter that can operate
from a wide range of voltage sources.
Independent input voltages for each
converter, Power Good outputs and an
LDO make the LTC3100 a small, highly
integrated and flexible solution for
many demanding applications.

L

Linear Technology Magazine • June 2008

Figure 3. Single-cell dual output converter with voltage sequencing

Figure 4. Voltage sequencing of the output
voltages for the circuit of Figure 3

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