LT1786F
PIN FUNCTIONS
AGND (Pin 5): This is the low current analog ground. It is
the negative sense terminal for the internal 1.24V refer-
ence and the ICCFL summing voltage in the LT1786F.
Connect low current signal paths that terminate to ground
and frequency compensation components that terminate
to ground directly to this pin for best regulation and
performance.
SHDN (Pin 6): Pulling this pin low causes regulator
shutdown with quiescent current typically reduced to
150µA. In this condition, the DAC circuitry remains alive
and the DAC IOUT level is maintained. If this pin is not used,
use a pull-up resistor to force a logic high level (maximum
of 6V). The pin can be floated and an internal current
source will pull the pin to a logic high level. However, poor
PCB layout techniques can permit switching noise to inject
into this pin and cause erratic operation. LTC recommends
the use of a pull-up resistor. If the SMBSUS pin is pulled
low or Bit 7 = 1 in the Command Byte, complete IC
shutdown is enabled. An internal open drain N-channel
device turns on and pulls the SHDN pin low. The N-channel
can sink up to 1.6mA.
SMBSUS (Pin 7): Pulling this pin low causes complete
shutdown for the IC with quiescent current typically
reduced to 40µA. In this SMBus suspend condition, the
DAC retains its last output current setting and returns to
this level when the logic low signal at this pin is removed.
If this pin is not used, use a pull-up resistor to force a
logic high level or tie it directly to VCC. Poor PCB layout
techniques can permit switching noise to inject into this
pin and cause erratic operation. A small value capacitor
may be required to filter out this noise. Setting Bit 7 = 1
in the Command Byte also enables an SMBus suspend
condition. Enabling an SMBus suspend condition turns
on an internal open drain N-channel device which pulls
the SHDN pin low. The N-channel device sinks up to
1.6mA at the SHDN pin.
ADR (Pin 8): This is the SMBus address select pin. Tie this
pin to either VCC or GND to select one of two SMBus
addresses to which the LT1786F will respond. If the ADR
pin is tied to GND, the SMBus address is set to 58 (HEX)
and the DAC IOUT powers up to zero scale. If the ADR pin
is tied to VCC, the SMBus address is set to 5A (HEX) and
the DAC IOUT powers up to half scale. If a different value is
required for the DAC IOUT on power-up, use the SHDN pin
to keep the CCFL regulator off until the required value has
been programmed for the DAC via the SMBus.
SDA (Pin 9): This is the SMBus bidirectional data input and
digital output pin. Data is shifted into the SDA pin and
acknowledged by the SDA pin. SDA is a high impedance
pin while data is shifted into the pin and an open-drain
N-channel output during acknowledges. SDA requires a
pull-up resistor or current source to VCC.
SCL (Pin 10): This is the SMBus clock input pin. Data is
shifted into the SDA pin at the rising edges of the SCL clock
during data transfer. SCL is a high impedance pin. SCL
requires a pull-up resistor or current source to VCC.
IOUT (Pin 11): This pin is the current output for the DAC and
provides a full-scale output current of 100µA ±4µA over
temperature. Initial accuracy is 100µA ±2µA.The pin can
be biased from – 10V to (VCC – 1.3V). This pin is typically
tied directly to the ICCFL pin and provides the programming
current which sets the operating lamp current. The IOUT
pin has very little bias voltage change when tied to the ICCFL
pin as ICCFL is regulated. The programming current is
sourced from the IOUT pin and sunk by the ICCFL pin.
VCC (Pin 12): This is the supply pin for the LT1786F. The
IC accepts an input voltage range of 3V minimum to 6.5V
maximum with little change in quiescent current (zero
switch current). An internal, low-dropout regulator pro-
vides a 2.4V supply for most of the internal circuitry.
Supply current increases as switch current increases at a
rate approximately 1/50 of switch current. This corre-
sponds to a forced Beta of 50 for the power switch. The IC
incorporates undervoltage lockout by sensing regulator
dropout and locking out switching for input voltages
below 2.5V. Hysteresis is not used to maximize the range
of input voltage. The typical input voltage is a 3.3V or 5V
logic supply.
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