NSC DAC101S101CIMK

DAC101S101
10-Bit Micro Power Digital-to-Analog Converter with
Rail-to-Rail Output
General Description
Features
The DAC101S101 is a full-featured, general purpose 10-bit
voltage-output digital-to-analog converter (DAC) that can
operate from a single +2.7V to 5.5V supply and consumes
just 175 µA of current at 3.6 Volts. The on-chip output
amplifier allows rail-to-rail output swing and the three wire
serial interface operates at clock rates up to 30 MHz over the
specified supply voltage range and is compatible with standard SPI™, QSPI, MICROWIRE and DSP interfaces. Competitive devices are limited to 20 MHz clock rates at supply
voltages in the 2.7V to 3.6V range.
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The supply voltage for the DAC101S101 serves as its voltage reference, providing the widest possible output dynamic
range. A power-on reset circuit ensures that the DAC output
powers up to zero volts and remains there until there is a
valid write to the device. A power-down feature reduces
power consumption to less than a microWatt.
The low power consumption and small packages of the
DAC101S101 make it an excellent choice for use in battery
operated equipment.
The DAC101S101 is a direct replacement for the AD5310
and is one of a family of pin compatible DACs, including the
8-bit DAC081S101 and the 12-bit DAC121S101. The
DAC101S101 operates over the extended industrial temperature range of −40˚C to +105˚C.
Guaranteed Monotonicity
Low Power Operation
Rail-to-Rail Voltage Output
Power-on Reset to Zero Volts Output
SYNC Interrupt Facility
Wide power supply range (+2.7V to +5.5V)
Small Packages
Power Down Feature
Key Specifications
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Resolution
10 bits
DNL
+0.15, -0.05 LSB (typ)
Output Settling Time
8 µs (typ)
Zero Code Error
3.3 mV (typ)
Full-Scale Error
−0.06 %FS (typ)
Power Consumption
— Normal Mode 0.63 mW (3.6V) / 1.41 mW (5.5V) typ
— Pwr Down Mode 0.14 µW (3.6V) / 0.33 µW (5.5V) typ
Applications
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Battery-Powered Instruments
Digital Gain and Offset Adjustment
Programmable Voltage & Current Sources
Programmable Attenuators
Pin Configuration
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20154101
Ordering Information
Order Numbers
Temperature Range
Package
DAC101S101CIMM
−40˚C ≤ TA ≤ +105˚C
MSOP
X62C
DAC101S101CIMMX
−40˚C ≤ TA ≤ +105˚C
MSOP Tape-and-Reel
X62C
DAC101S101CIMK
−40˚C ≤ TA ≤ +105˚C
TSOT
X63C
DAC101S101CIMKX
−40˚C ≤ TA ≤ +105˚C
TSOT Tape-and-Reel
X63C
DAC101S101EVAL
Top Mark
Evaluation Board
SPI™ is a trademark of Motorola, Inc.
© 2005 National Semiconductor Corporation
DS201541
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DAC101S101 10-Bit Micro Power Digital-to-Analog Converter with Rail-to-Rail Output
June 2005
DAC101S101
Block Diagram
20154103
Pin Descriptions
TSOT
(SOT-23)
Pin No.
MSOP
Pin No.
Symbol
Description
1
4
VOUT
DAC Analog Output Voltage.
2
8
GND
Ground reference for all on-chip circuitry.
3
1
VA
Power supply and Reference input. Should be decoupled
to GND.
4
7
DIN
Serial Data Input. Data is clocked into the 16-bit shift
register on the falling edges of SCLK after the fall of
SYNC.
5
6
SCLK
Serial Clock Input. Data is clocked into the input shift
register on the falling edges of this pin.
5
SYNC
Frame synchronization input for the data input. When this
pin goes low, it enables the input shift register and data
is transferred on the falling edges of SCLK. The DAC is
updated on the 16th clock cycle unless SYNC is brought
high before the 16th clock, in which case the rising edge
of SYNC acts as an interrupt and the write sequence is
ignored by the DAC.
2, 3
NC
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No Connect. There is no internal connection to these
pins.
2
Storage Temperature
−65˚C to +150˚C
(Notes 1, 2)
Operating Ratings (Notes 1, 2)
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
Operating Temperature Range
6.5V
Supply Voltage, VA
Voltage on any Input Pin
Package Input Current (Note 3)
Power Consumption at TA = 25˚C
ESD Susceptibility (Note 5)
Human Body Model
Machine Model
Soldering Temperature, Infrared,
10 Seconds (Note 6)
+2.7V to 5.5V
Any Input Voltage (Note 7)
−0.3V to (VA + 0.3V)
Input Current at Any Pin (Note 3)
−40˚C ≤ TA ≤ +105˚C
Supply Voltage, VA
−0.1 V to (VA + 0.1 V)
Output Load
10 mA
0 to 1500 pF
SCLK Frequency
20 mA
See (Note 4)
Up to 30 MHz
Package Thermal Resistances
2500V
250V
Package
θJA
8-Lead MSOP
240˚C/W
6-Lead TSOT
250˚C/W
235˚C
Electrical Characteristics
Values shown in this table are design targets and are subject to change before product release. The following specifications apply for VA = +2.7V to +5.5V, RL = 2kΩ to GND, CL = 200 pF to GND, fSCLK = 30 MHz, input code range 12 to 1011.
Boldface limits apply for TMIN ≤ TA ≤ TMAX: all other limits TA = 25˚C, unless otherwise specified.
Symbol
Parameter
Conditions
Typical
(Note 9)
Limits
(Note 9)
Units
(Limits)
10
Bits (min)
STATIC PERFORMANCE
Resolution
Monotonicity
INL
Integral Non-Linearity
DNL
Differential Non-Linearity
10
Bits (min)
Over Decimal codes 12 to 1011
± 0.6
± 2.8
LSB (max)
VA = 2.7V to 5.5V
+0.15
+0.35
LSB (max)
−0.05
−0.2
LSB (min)
ZE
Zero Code Error
IOUT = 0
+3.3
+15
mV (max)
FSE
Full-Scale Error
IOUT = 0
−0.06
−1.0
%FSR
(max)
GE
Gain Error
All ones Loaded to DAC register
−0.10
± 1.0
%FSR
(max)
−20
µV/˚C
VA = 3V
−0.7
ppm/˚C
VA = 5V
−1.0
ppm/˚C
ZCED
TC GE
Zero Code Error Drift
Gain Error Tempco
OUTPUT CHARACTERISTICS
Output Voltage Range
ZCO
FSO
Zero Code Output
Full Scale Output
Maximum Load Capacitance
0
VA
(Note 10)
V (min)
V (max)
VA = 3V, IOUT = 10 µA
1.8
mV
VA = 3V, IOUT = 100 µA
5.0
mV
VA = 5V, IOUT = 10 µA
3.7
mV
VA = 5V, IOUT = 100 µA
5.4
mV
VA = 3V, IOUT = 10 µA
2.997
V
VA = 3V, IOUT = 100 µA
2.990
V
VA = 5V, IOUT = 10 µA
4.995
V
VA = 5V, IOUT = 100 µA
RL = ∞
4.992
V
1500
pF
RL = 2kΩ
1500
pF
1.3
Ohm
DC Output Impedance
3
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DAC101S101
Absolute Maximum Ratings
DAC101S101
Electrical Characteristics
(Continued)
Values shown in this table are design targets and are subject to change before product release. The following specifications apply for VA = +2.7V to +5.5V, RL = 2kΩ to GND, CL = 200 pF to GND, fSCLK = 30 MHz, input code range 12 to 1011.
Boldface limits apply for TMIN ≤ TA ≤ TMAX: all other limits TA = 25˚C, unless otherwise specified.
Symbol
IOS
Parameter
Output Short Circuit Current
Typical
(Note 9)
Conditions
Limits
(Note 9)
Units
(Limits)
VA = 5V, VOUT = 0V,
Input code = 3FFh
−63
mA
VA = 3V, VOUT = 0V,
Input code = 3FFh
−50
mA
VA = 5V, VOUT = 5V,
Input code = 000h
74
mA
VA = 3V, VOUT = 3V,
Input code = 000h
53
mA
LOGIC INPUT
IIN
Input Current (Note 10)
VIL
Input Low Voltage (Note 10)
VIH
Input High Voltage (Note 10)
CIN
Input Capacitance (Note 10)
±1
µA (max)
VA = 5V
0.8
V (max)
VA = 3V
0.5
V (max)
VA = 5V
2.4
V (min)
VA = 3V
2.1
V (min)
3
pF (max)
POWER REQUIREMENTS
Normal Mode
fSCLK = 30 MHz
IA
Supply Current (output
unloaded)
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VA = 3.6V
226
µA (max)
221
297
µA (max)
VA = 3.6V
154
207
µA (max)
Normal Mode
fSCLK = 0
VA = 5.5V
145
µA (max)
VA = 3.6V
113
µA (max)
VA = 5.0V
83
µA (max)
VA = 3.0V
42
µA (max)
VA = 5.0V
56
µA (max)
VA = 3.0V
28
VA = 5.5V
0.06
VA = 3.6V
All PD Modes,
fSCLK = 30 MHz
µA (max)
1.0
µA (max)
0.04
1.0
µA (max)
Normal Mode
fSCLK = 30 MHz
VA = 5.5V
1.41
1.83
mW (max)
VA = 3.6V
0.63
0.81
mW (max)
Normal Mode
fSCLK = 20 MHz
VA = 5.5V
1.22
1.63
mW (max)
VA = 3.6V
0.55
0.74
mW (max)
Normal Mode
fSCLK = 0
VA = 5.5V
0.80
µW (max)
VA = 3.6V
0.41
µW (max)
All PD Modes,
fSCLK = 30 MHz
VA = 5.0V
0.42
µW (max)
VA = 3.0V
0.13
µW (max)
VA = 5.0V
0.28
µW (max)
VA = 3.0V
0.08
VA = 5.5V
0.33
5.5
µW (max)
VA = 3.6V
0.14
3.6
µW (max)
All PD Modes,
fSCLK = 0 (Note 10)
Power Efficiency
µA (max)
174
All PD Modes,
fSCLK = 20 MHz
IOUT / IA
332
VA = 5.5V
All PD Modes,
fSCLK = 0 (Note 10)
Power Consumption (output
unloaded)
256
Normal Mode
fSCLK = 20 MHz
All PD Modes,
fSCLK = 20 MHz
PC
VA = 5.5V
ILOAD = 2mA
4
µW (max)
VA = 5V
91
%
VA = 3V
94
%
Values shown in this table are design targets and are subject to change before product release. The following specifications apply for VA = +2.7V to +5.5V, RL = 2kΩ to GND, CL = 200 pF to GND, fSCLK = 30 MHz, input code range 12 to 1011.
Boldface limits apply for TMIN ≤ TA ≤ TMAX: all other limits TA = 25˚C, unless otherwise specified.
Symbol
Parameter
fSCLK
SCLK Frequency
ts
Output Voltage Settling Time
(Note 10)
SR
Output Slew Rate
Glitch Impulse
Conductions
100h to 300h code
change, RL = 2kΩ
CL ≤ 200 pF
Wake-Up Time
1/fSCLK
SCLK Cycle Time
tH
SCLK High time
tL
SCLK Low Time
5
Limits
Units
(Limits)
30
MHz (max)
7.5
µs (max)
1
V/µs
12
nV-sec
0.5
nV-sec
VA = 5V
1.6
µs
VA = 3V
1.9
Code change from 200h to 1FFh
Digital Feedthrough
tWU
Typical
µs
33
ns (min)
5
13
ns (min)
5
13
ns (min)
tSUCL
Set-up Time SYNC to SCLK Rising
Edge
−15
0
ns (min)
tSUD
Data Set-Up Time
2.5
5
ns (min)
tDHD
Data Hold Time
2.5
4.5
ns (min)
VA = 5V
0
3
ns (min)
VA = 3V
−2
1
ns (min)
2.7 ≤ VA ≤ 3.6
9
20
ns (min)
3.6 ≤ VA ≤ 5.5
5
10
ns (min)
tCS
SCLK fall to rise of SYNC
tSYNC
SYNC High Time
Note 1: Absolute Maximum Ratings indicate limits beyond which damage to the device may occur. Operating Ratings indicate conditions for which the device is
functional, but do not guarantee specific performance limits. For guaranteed specifications and test conditions, see the Electrical Characteristics. The guaranteed
specifications apply only for the test conditions listed. Some performance characteristics may degrade when the device is not operated under the listed test
conditions.
Note 2: All voltages are measured with respect to GND = 0V, unless otherwise specified
Note 3: When the input voltage at any pin exceeds the power supplies (that is, less than GND, or greater than VA), the current at that pin should be limited to 10
mA. The 20 mA maximum package input current rating limits the number of pins that can safely exceed the power supplies with an input current of 10 mA to two.
Note 4: The absolute maximum junction temperature (TJmax) for this device is 150˚C. The maximum allowable power dissipation is dictated by TJmax, the
junction-to-ambient thermal resistance (θJA), and the ambient temperature (TA), and can be calculated using the formula PDMAX = (TJmax − TA) / θJA. The values
for maximum power dissipation will be reached only when the device is operated in a severe fault condition (e.g., when input or output pins are driven beyond the
power supply voltages, or the power supply polarity is reversed). Obviously, such conditions should always be avoided.
Note 5: Human body model is 100 pF capacitor discharged through a 1.5 kΩ resistor. Machine model is 220 pF discharged through ZERO Ohms.
Note 6: See the section entitled "Surface Mount" found in any post 1986 National Semiconductor Linear Data Book for methods of soldering surface mount devices.
Note 7: The analog inputs are protected as shown below. Input voltage magnitudes up to VA + 300 mV or to 300 mV below GND will not damage this device.
However, errors in the conversion result can occur if any input goes above VA or below GND by more than 100 mV. For example, if VA is 2.7VDC, ensure that −100mV
≤ input voltages ≤2.8VDC to ensure accurate conversions.
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Note 8: To guarantee accuracy, it is required that VA be well bypassed.
Note 9: Typical figures are at TJ = 25˚C, and represent most likely parametric norms. Test limits are guaranteed to National’s AOQL (Average Outgoing Quality
Level).
Note 10: This parameter is guaranteed by design and/or characterization and is not tested in production.
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DAC101S101
A.C. and Timing Characteristics
DAC101S101
LSB = VREF / 2n
where VREF is the supply voltage for this product, and "n" is
the DAC resolution in bits, which is 10 for the DAC101S101.
Specification Definitions
DIFFERENTIAL NON-LINEARITY (DNL) is the measure of
the maximum deviation from the ideal step size of 1 LSB,
which is VREF / 1024 = VA / 1024.
MAXIMUM LOAD CAPACITANCE is the maximum capacitance that can be driven by the DAC with output stability
maintained.
DIGITAL FEEDTHROUGH is a measure of the energy injected into the analog output of the DAC from the digital
inputs when the DAC outputs are not updated. It is measured with a full-scale code change on the data bus.
MONOTONICITY is the condition of being monotonic, where
the DAC has an output that never decreases when the input
code increases.
FULL-SCALE ERROR is the difference between the actual
output voltage with a full scale code (3FFh) loaded into the
DAC and the value of VA x 1023 / 1024.
GAIN ERROR is the deviation from the ideal slope of the
transfer function. It can be calculated from Zero and FullScale Errors as GE = FSE - ZE, where GE is Gain error, FSE
is Full-Scale Error and ZE is Zero Error.
MOST SIGNIFICANT BIT (MSB) is the bit that has the
largest value or weight of all bits in a word. Its value is 1/2 of
V A.
POWER EFFICIENCY is the ratio of the output current to the
total supply current. The output current comes from the
power supply. The difference between the supply and output
currents, is the power consumed by the device without a
load.
GLITCH IMPULSE is the energy injected into the analog
output when the input code to the DAC register changes. It is
specified as the area of the glitch in nanovolt-seconds.
SETTLING TIME is the time for the output to settle within 1/2
LSB of the final value after the input code is updated.
INTEGRAL NON-LINEARITY (INL) is a measure of the
deviation of each individual code from a straight line through
the input to output transfer function. The deviation of any
given code from this straight line is measured from the
center of that code value. The end point method is used. INL
for this product is specified over a limited range, per the
Electrical Tables.
LEAST SIGNIFICANT BIT (LSB) is the bit that has the
smallest value or weight of all bits in a word. This value is
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WAKE-UP TIME is the time for the output to settle to within
1/2 LSB of the final value after the device is commanded to
the active mode from any of the power down modes.
ZERO CODE ERROR is the output error, or voltage, present
at the DAC output after a code of 000h has been entered.
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DAC101S101
Transfer Characteristic
20154105
FIGURE 1. Input / Output Transfer Characteristic
Timing Diagram
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FIGURE 2. DAC101S101 Timing
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DAC101S101
Typical Performance Characteristics
fSCLK = 30 MHz, TA = 25C, Input Code Range 12 to 1011,
unless otherwise stated
DNL at VA = 3.0V
DNL at VA = 5.0V
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INL at VA = 3.0V
INL at VA = 5.0V
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TUE at VA = 3.0V
TUE at VA = 5.0V
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20154157
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DNL vs. VA
INL vs. VA
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20154123
3V DNL vs. fSCLK
5V DNL vs. fSCLK
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20154151
3V DNL vs. Clock Duty Cycle
5V DNL vs. Clock Duty Cycle
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DAC101S101
Typical Performance Characteristics fSCLK = 30 MHz, TA = 25C, Input Code Range 12 to 1011,
unless otherwise stated (Continued)
DAC101S101
Typical Performance Characteristics fSCLK = 30 MHz, TA = 25C, Input Code Range 12 to 1011,
unless otherwise stated (Continued)
3V DNL vs. Temperature
5V DNL vs. Temperature
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3V INL vs. fSCLK
5V INL vs. fSCLK
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20154129
3V INL vs. Clock Duty Cycle
5V INL vs. Clock Duty Cycle
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20154131
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3V INL vs. Temperature
5V INL vs. Temperature
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20154133
Zero Code Error vs. fSCLK
Zero Code Error vs. Clock Duty Cycle
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Zero Code Error vs. Temperature
Full-Scale Error vs. fSCLK
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DAC101S101
Typical Performance Characteristics fSCLK = 30 MHz, TA = 25C, Input Code Range 12 to 1011,
unless otherwise stated (Continued)
DAC101S101
Typical Performance Characteristics fSCLK = 30 MHz, TA = 25C, Input Code Range 12 to 1011,
unless otherwise stated (Continued)
Full-Scale Error vs. Clock Duty Cycle
Full-Scale Error vs. Temperature
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Supply Current vs. VA
Supply Current vs. Temperature
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5V Glitch Response
Power-On Reset
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12
3V Wake-Up Time
5V Wake-Up Time
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DAC101S101
Typical Performance Characteristics fSCLK = 30 MHz, TA = 25C, Input Code Range 12 to 1011,
unless otherwise stated (Continued)
DAC101S101
brought high. In either case, it must be brought high for the
minimum specified time before the next write sequence as a
falling edge of SYNC is used to initiate the next write cycle.
Since the SYNC and DIN buffers draw more current when
they are high, they should be idled low between write sequences to minimize power consumption.
1.0 Functional Description
1.1 DAC SECTION
The DAC101S101 is fabricated on a CMOS process with an
architecture that consists of switches and a resistor string
that are followed by an output buffer. The power supply
serves as the reference voltage. The input coding is straight
binary with an ideal output voltage of:
VOUT = VA x (D / 1024)
1.5 INPUT SHIFT REGISTER
The input shift register, Figure 4, has sixteen bits. The first
two bits are "don’t cares" and are followed by two bits that
determine the mode of operation (normal mode or one of
three power-down modes). The contents of the serial input
register are transferred to the DAC register on the sixteenth
falling edge of SCLK. See Timing Diagram, Figure 2.
where D is the decimal equivalent of the binary code that is
loaded into the DAC register and can take on any value
between 0 and 1023.
1.2 RESISTOR STRING
The resistor string is shown in Figure 3. This string consists
of 4096 equal valued resistors with a switch at each junction
of two resistors, plus a switch to ground. The code loaded
into the DAC register determines which switch is closed,
connecting the proper node to the amplifier. This configuration guarantees that the DAC is monotonic.
20154108
FIGURE 4. Input Register Contents
Normally, the SYNC line is kept low for at least 16 falling
edges of SCLK and the DAC is updated on the 16th SCLK
falling edge. However, if SYNC is brought high before the
16th falling edge, the shift register is reset and the write
sequence is invalid. The DAC register is not updated and
there is no change in the mode of operation or in the output
voltage.
1.6 POWER-ON RESET
The power-on reset circuit controls the output voltage during
power-up. Upon application of power the DAC register is
filled with zeros and the output voltage is 0 Volts and remains
there until a valid write sequence is made to the DAC.
1.7 POWER-DOWN MODES
The DAC101S101 has four modes of operation. These
modes are set with two bits (DB13 and DB12) in the control
register.
20154107
FIGURE 3. DAC Resistor String
TABLE 1. Modes of Operation
1.3 OUTPUT AMPLIFIER
The output buffer amplifier is a rail-to-rail type, providing an
output voltage range of 0V to VA. All amplifiers, even rail-torail types, exhibit a loss of linearity as the output approaches
the supply rails (0V and VA, in this case). For this reason,
linearity is specified over less than the full output range of the
DAC. The output capabilities of the amplifier are described in
the Electrical Tables.
DB12
0
0
Operating Mode
Normal Operation
0
1
Power-Down with 1kΩ to GND
1
0
Power-Down with 100kΩ to GND
1
1
Power-Down with Hi-Z
When both DB13 and DB12 are 0, the device operates
normally. For the other three possible combinations of these
bits the supply current drops to its power-down level and the
output is pulled down with either a 1kΩ or a 100KΩ resistor,
or is in a high impedance state, as described in Table 1.
The bias generator, output amplifier, the resistor string and
other linear circuitry are all shut down in any of the powerdown modes. However, the contents of the DAC register are
unaffected when in power-down, so when coming out of
power down the output voltage returns to the same voltage it
1.4 SERIAL INTERFACE
The three-wire interface is compatible with SPI, QSPI and
MICROWIRE as well as most DSPs. See the Timing Diagram for information on a write sequence.
A write sequence begins by bringing the SYNC line low.
Once SYNC is low, the data on the DIN line is clocked into
the 16-bit serial input register on the falling edges of SCLK.
On the 16th falling clock edge, the last data bit is clocked in
and the programmed function (a change in the mode of
operation and/or a change in the DAC register contents) is
executed. At this point the SYNC line may be kept low or
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DB13
14
2.1.3 68HC11 Interface
(Continued)
A serial interface between the DAC101S101 and the
68HC11 microcontroller is shown in Figure 7. The SYNC line
of the DAC101S101 is driven from a port line (PC7 in the
figure), similar to the 80C51/80L51.
was before entering power down. Minimum power consumption is achieved in the power-down mode with SCLK disabled and SYNC and DIN idled low.
The 68HC11 should be configured with its CPOL bit as a
zero and its CPHA bit as a one. This configuration causes
data on the MOSI output to be valid on the falling edge of
SCLK. PC7 is taken low to transmit data to the DAC. The
68HC11 transmits data in 8-bit bytes with eight falling clock
edges. Data is transmitted with the MSB first. PC7 must
remain low after the first eight bits are transferred. A second
write cycle is initiated to transmit the second byte of data to
the DAC, after which PC7 should be raised to end the write
sequence.
2.0 Applications Information
The simplicity of the DAC101S101 implies ease of use.
However, it is important to recognize that any data converter
that utilizes its supply voltage as its reference voltage will
have essentially zero PSRR (Power Supply Rejection Ratio).
Therefore, it is necessary to provide a noise-free supply
voltage to the device.
2.1 DSP/MICROPROCESSOR INTERFACING
Interfacing the DAC101S101 to microprocessors and DSPs
is quite simple. The following guidelines are offered to hasten the design process.
2.1.1 ADSP-2101/ADSP2103 Interfacing
Figure 5 shows a serial interface between the DAC101S101
and the ADSP-2101/ADSP2103. The DSP should be set to
operate in the SPORT Transmit Alternate Framing Mode. It is
programmed through the SPORT control register and should
be configured for Internal Clock Operation, Active Low Framing and 16-bit Word Length. Transmission is started by
writing a word to the Tx register after the SPORT mode has
been enabled.
20154111
FIGURE 7. 68HC11 Interface
2.1.4 Microwire Interface
Figure 8 shows an interface between a Microwire compatible
device and the DAC101S101. Data is clocked out on the
rising edges of the SCLK signal.
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20154112
FIGURE 5. ADSP-2101/2103 Interface
FIGURE 8. Microwire Interface
2.1.2 80C51/80L51 Interface
A serial interface between the DAC101S101 and the 80C51/
80L51 microcontroller is shown in Figure 6. The SYNC signal
comes from a bit-programmable pin on the microcontroller.
The example shown here uses port line P3.3. This line is
taken low when data is to transmitted to the DAC101S101.
Since the 80C51/80L51 transmits 8-bit bytes, only eight
falling clock edges occur in the transmit cycle. To load data
into the DAC, the P3.3 line must be left low after the first
eight bits are transmitted. A second write cycle is initiated to
transmit the second byte of data, after which port line P3.3 is
brought high. The 80C51/80L51 transmit routine must recognize that the 80C51/80L51 transmits data with the LSB
first while the DAC101S101 requires data with the MSB first.
2.2 USING REFERENCES AS POWER SUPPLIES
Recall the need for a quiet supply source for devices that use
their power supply voltage as a reference voltage.
Since the DAC101S101 consumes very little power, a reference source may be used as the supply voltage. The advantages of using a reference source over a voltage regulator
are accuracy and stability. Some low noise regulators can
also be used for the power supply of the DAC101S101.
Listed below are a few power supply options for the
DAC101S101.
2.2.1 LM4130
The LM4130 reference, with its 0.05% accuracy over temperature, is a good choice as a power source for the
DAC101S101. Its primary disadvantage is the lack of 3V and
5V versions. However, the 4.096V version is useful if a 0 to
4.095V output range is desirable or acceptable. Bypassing
the LM4130 VIN pin with a 0.1µF capacitor and the VOUT
pin with a 2.2µF capacitor will improve stability and reduce
output noise. The LM4130 comes in a space-saving 5-pin
SOT23.
20154110
FIGURE 6. 80C51/80L51 Interface
15
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DAC101S101
1.0 Functional Description
DAC101S101
2.0 Applications Information
LM4050 for proper regulation, IA(max) is the maximum
DAC101S101 supply current, and IA(min) is the minimum
DAC101S101 supply current.
(Continued)
2.2.3 LP3985
The LP3985 is a low noise, ultra low dropout voltage regulator with a 3% accuracy over temperature. It is a good
choice for applications that do not require a precision reference for the DAC101S101. It comes in 3.0V, 3.3V and 5V
versions, among others, and sports a low 30 µV noise specification at low frequencies. Since low frequency noise is
relatively difficult to filter, this specification could be important
for some applications. The LP3985 comes in a space-saving
5-pin SOT23 and 5-bump micro SMD packages.
20154113
FIGURE 9. The LM4130 as a power supply
2.2.2 LM4050
Available with accuracy of 0.44%, the LM4050 shunt reference is also a good choice as a power regulator for the
DAC101S101. It does not come in a 3 Volt version, but
4.096V and 5V versions are available. It comes in a spacesaving 3-pin SOT23.
20154115
FIGURE 11. Using the LP3985 regulator
An input capacitance of 1.0µF without any ESR requirement
is required at the LP3985 input, while a 1.0µF ceramic
capacitor with an ESR requirement of 5mΩ to 500mΩ is
required at the output. Careful interpretation and understanding of the capacitor specification is required to ensure
correct device operation.
2.2.4 LP2980
The LP2980 is an ultra low dropout regulator with a 0.5% or
1.0% accuracy over temperature, depending upon grade. It
is available in 3.0V, 3.3V and 5V versions, among others.
20154114
FIGURE 10. The LM4050 as a power supply
The minimum resistor value in the circuit of Figure 10 should
be chosen such that the maximum current through the
LM4050 does not exceed its 15 mA rating. The conditions for
maximum current include the input voltage at its maximum,
the LM4050 voltage at its minimum, the resistor value at its
minimum due to tolerance, and the DAC101S101 draws
zero current. The maximum resistor value must allow the
LM4050 to draw more than its minimum current for regulation plus the maximum DAC101S101 current in full operation. The conditions for minimum current include the input
voltage at its minimum, the LM4050 voltage at its maximum,
the resistor value at its maximum due to tolerance, and the
DAC101S101 draws its maximum current. These conditions
can be summarized as
R(min) = ( VIN(max) − VZ(min) / (IA(min) + IZ(max))
and
R(max) = ( VIN(min) − VZ(max) / (IA(max) + IZ(min) )
where VZ(min) and VZ(max) are the nominal LM4050 output
voltages ± the LM4050 output tolerance over temperature,
IZ(max) is the maximum allowable current through the
LM4050, IZ(min) is the minimum current required by the
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20154116
FIGURE 12. Using the LP2980 regulator
Like any low dropout regulator, the LP2980 requires an
output capacitor for loop stability. This output capacitor must
be at least 1.0µF over temperature, but values of 2.2µF or
more will provide even better performance. The ESR of this
capacitor should be within the range specified in the LP2980
data sheet. Surface-mount solid tantalum capacitors offer a
good combination of small size and ESR. Ceramic capacitors are attractive due to their small size but generally have
ESR values that are too low for use with the LP2980. Alumi-
16
2.4 LAYOUT, GROUNDING, AND BYPASSING
For best accuracy and minimum noise, the printed circuit
board containing the DAC101S101 should have separate
analog and digital areas. The areas are defined by the
locations of the analog and digital power planes. Both of
these planes should be located in the same board layer.
There should be a single ground plane. A single ground
plane is preferred if digital return current does not flow
through the analog ground area. Frequently a single ground
plane design will utilize a "fencing" technique to prevent the
mixing of analog and digital ground current. Separate ground
planes should only be utilized when the fencing technique is
inadequate. The separate ground planes must be connected
in one place, preferably near the DAC101S101. Special care
is required to guarantee that digital signals with fast edge
rates do not pass over split ground planes. They must always have a continuous return path below their traces.
(Continued)
num electrolytic capacitors are typically not a good choice
due to their large size and have ESR values that may be too
high at low temperatures.
2.3 BIPOLAR OPERATION
The DAC101S101 is designed for single supply operation
and thus has a unipolar output. However, a bipolar output
may be obtained with the circuit in Figure 13. This circuit will
provide an output voltage range of ± 5 Volts. A rail-to-rail
amplifier should be used if the amplifier supplies are limited
to ± 5V.
The DAC101S101 power supply should be bypassed with a
10µF and a 0.1µF capacitor as close as possible to the
device with the 0.1µF right at the device supply pin. The
10µF capacitor should be a tantalum type and the 0.1µF
capacitor should be a low ESL, low ESR type. The power
supply for the DAC101S101 should only be used for analog
circuits.
Avoid crossover of analog and digital signals and keep the
clock and data lines on the component side of the board. The
clock and data lines should have controlled impedances.
20154117
FIGURE 13. Bipolar Operation
The output voltage of this circuit for any code is found to be
VO = (VA x (D / 1024) x ((R1 + R2) / R1) - VA x R2 / R1)
where D is the input code in decimal form. With VA = 5V and
R1 = R2,
VO = (10 x D / 1024) - 5V
A list of rail-to-rail amplifiers suitable for this application are
indicated in Table 2.
TABLE 2. Some Rail-to-Rail Amplifiers
AMP
PKGS
LMC7111
DIP-8
SOT23-5
Typ VOS
Typ ISUPPLY
0.9 mV
25 µA
LM7301
SO-8
SOT23-5
0.03 mV
620 µA
LM8261
SOT23-5
0.7 mV
1 mA
17
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DAC101S101
2.0 Applications Information
DAC101S101
Physical Dimensions
inches (millimeters)
unless otherwise noted
8-Lead MSOP
Order Numbers DAC101S101CIMM
NS Package Number MUA08A
6-Lead TSOT
Order Numbers DAC101S101CIMK
NS Package Number MK06A
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18
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DAC101S101 10-Bit Micro Power Digital-to-Analog Converter with Rail-to-Rail Output
Notes