LTC1450/LTC1450L
U
OPERATION
is not internally connected to the DAC resistor string, an
external reference can be used or the resistor string can be
driven with an external source in multiplying configura-
tion. The external reference or source must be capable of
driving the 8k minimum DAC ladder resistance.
The data on the input of the DAC is loaded into the DAC’s
input latches when Chip Select (CSLSB and/or CSMSB)
and WR are at a logic low. The data that is loaded into the
inputlatcheswilldependonwhichoftheChipSelectsare
at a logic low (see Digital Interface Truth Table). If WR
and CSLSB are both low and CSMSB is high, then only
data on the eight LSBs (D0 to D7) is loaded into the input
latches. Similarly if WR and CSMSB are both low and
CSLSB is high then only data on the four MSBs (D8 to
D11)isloadedintotheinputlatches.Dataisloadedintoboth
the Least Significant Data Bits (D0 to D7) and the Most
Significant Bits (D8 to D11) at the same time if WR, CSLSB
and CSMSB are low.
The reference output noise can be reduced with a bypass
capacitor to ground. (Note: The reference does not require
a bypass capacitor to ground for proper operation.) When
bypassing the reference a small value resistor in series
with the capacitor is recommended to help reduce peaking
on the output. A 10Ω resistor in series with a 4.7µF
capacitor is optimum for reducing reference generated
noise.
Theinputdataislatchedintotheinputlatchesontherising
edge of either the WR or one of the Chip Selects. The WR
transition high will latch the data in both input latches. A
rising edge on CSMSB will latch data bits D8 to D11. A
rising edge on CSLSB will latch data bits D0 to D7.
The high and low end of the DAC ladder resistor string
(REFHI and REFLO respectively) are not connected inter-
nally on this part. Typically REFHI will be connected to
REFOUT and REFLO will be connected to GND. This will
give the LTC1450 a full-scale range of 4.095V. The full-
scale range for the LTC1450L will be 2.5V
Once data is loaded into the input latches, it can be loaded
into the DAC latch. This will update the analog voltage
output of the DAC. The DAC latch is loaded by a logic low
on LDAC. The data that is loaded into the DAC latch will be
latched on the rising edge of LDAC.
Either of these pins can be driven up to VCC – 1.5V when
using the buffer in the gain of 1 configuration. The resistor
string pins can be driven to VCC/2 when the buffer is in the
gain of 2 configuration (2.05 for the LTC1450L). The
resistance between these two pins is typically 18k (8k
min).
When WR, CSLSB, CSMSB and LDAC are all low the
latches are transparent and data on pins D0 to D11 loads
directly into the DAC latch.
The output buffer for the LTC1450/LTC1450L can be
configured for two different gain settings. By tying the
X1/X2 pin to GND the gain is set to 2 (2.05 for the
LTC1450L). By tying the X1/X2 pin to VOUT the gain is set
to one.
The LTC1450/LTC1450L have an internal power-on reset
that resets all internal latches to 0’s on power-up (equiva-
lent to the CLR pin function).
TheLTC1450family’srail-to-railbufferedoutputcansource
or sink 5mA over the entire operating temperature range
while pulling to within 300mV of the positive supply
voltage or GND. The output swings to within a few milli-
volts of either supply rail when unloaded and has an
equivalent output resistance of 40Ω when driving a load to
the rails.
The LTC1450 includes an internal 2.048V reference, giv-
ing the LTC1450 a full-scale range of 4.095V in the gain of
2 configuration. The LTC1450L has an internal 1.22V
reference with a full-scale range of 2.5V and a gain of 2.05
inthegainof2configuration. Theonboardreferenceinthe
LTC1450 and LTC1450L is not internally connected to the
DAC’s reference resistor string but is provided on an
adjacent pin for flexibility. Because the internal reference
10
Linear [ Linear ]
