LTC1657L データシートの表示(PDF) - Linear Technology
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LTC1657L Datasheet PDF : 12 Pages
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OPERATION
Parallel Interface
The data on the input of the DAC is written into the DAC’s
input registers when Chip Select (CSLSB and/or CSMSB)
and WR are at a logic low. The data that is written into the
input registers will depend on which of the Chip Selects
are 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 written into the input
registers. Similarly, if WR and CSMSB are both low and
CSLSB is high, then only data on the eight MSBs (D8 to
D15) is written into the input registers. Data is written into
both the Least Significant Data Bits (D0 to D7) and the Most
Significant Bits (D8 to D15) at the same time if WR, CSLSB
and CSMSB are low. If WR is high or both CSMSB and
CSLSB are high, then no data is written into the input
registers.
Once data is written into the input registers, it can be
written into the DAC register. This will update the analog
voltage output of the DAC. The DAC register is written by
a logic low on LDAC. The data in the DAC register will be
held when LDAC is high.
When WR, CSLSB, CSMSB and LDAC are all low, the
registers are transparent and data on pins D0 to D15 flows
directly into the DAC register.
For an 8-bit data bus connection, tie the MSB byte data
pins to their corresponding LSB byte pins (D15 to D7, D14
to D6, etc).
Power-On Reset
The LTC1657L has an internal power-on reset that resets
all internal registers to 0’s on power-up (equivalent to the
CLR pin function).
Reference
The LTC1657L includes an internal 1.25V reference, giv-
ing the LTC1657L a full-scale range of 2.5V in the gain-of-
2 configuration. The onboard reference in the LTC1657L is
not internally connected to the DAC’s reference resistor
string but is provided on an adjacent pin for flexibility.
Because the internal reference is not internally connected
to the DAC resistor ladder, an external reference can be
LTC1657L
used or the resistor ladder can be driven by an external
source in multiplying applications. The external reference
or source must be capable of driving the 16k (minimum)
DAC ladder resistance.
Internal reference output voltage noise spectral density
can be reduced with a bypass capacitor to ground. (Note:
The reference does not require a bypass capacitor to
ground for nominal operation.) When bypassing the refer-
ence, 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. Internal reference
output noise at 1kHz is typically 80nV/√Hz.
DAC Resistor Ladder
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. X1/X2
connected to GND will give the LTC1657L a full-scale
output swing of 2.5V.
Either of these pins can be driven up to VCC – 1.5V when
using the buffer in the gain-of-1 configuration. The resis-
tor string pins can be driven to VCC/2 when the buffer is in
the gain of 2 configuration. The resistance between these
two pins is typically 30k (16k min).
Voltage Output
The output buffer for the LTC1657L can be configured for
two different gain settings. By tying the X1/X2 pin to GND,
the gain is set to 2. By tying the X1/X2 pin to VOUT, the gain
is set to unity.
The LTC1657L rail-to-rail buffered output can source or
sink 5mA to within 500mV of the positive supply voltage
or ground at room temperature. The output stage is
equipped with a deglitcher that results in a midscale glitch
impulse of 8nV • s. The output swings to within a few
millivolts of either supply rail when unloaded and has an
equivalent output resistance of 40Ω when driving a load to
the rails.
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