NSC DAC1232LIN, DAC1232LCWMX, DAC1232LCWM, DAC1232LCN, DAC1232LCJ Datasheet

...
TL/H/5690
MICRO-DAC DAC1208/DAC1209/DAC1210/DAC1230/DAC1231/DAC1232
12-Bit, mP Compatible, Double-Buffered D to A Converters
February 1995
MICRO-DACTMDAC1208/DAC1209/DAC1210/DAC1230/ DAC1231/DAC1232 12-Bit, mP Compatible, Double-Buffered D to A Converters
General Description
The DAC1208 and the DAC1230 series are 12-bit multiply­ing D to A converters designed to interface directly with a wide variety of microprocessors (8080, 8048, 8085, Z-80, etc.). Double buffering input registers and associated con­trol lines allow these DACs to appear as a two-byte ‘‘stack’’ in the system’s memory or I/O space with no additional in­terfacing logic required.
The DAC1208 series provides all 12 input lines to allow sin­gle buffering for maximum throughput when used with 16-bit processors. These input lines can also be externally config­ured to permit an 8-bit data interface. The DAC1230 series can be used with an 8-bit data bus directly as it internally formulates the 12-bit DAC data from its 8 input lines. All of these DACs accept left-justified data from the processor.
The analog section is a precision silicon-chromium (Si-Cr) R-2R ladder network and twelve CMOS current switches. An inverted R-2R ladder structure is used with the binary weighted currents switched between the I
OUT1
and I
OUT2
maintaining a constant current in each ladder leg indepen­dent of the switch state. Special circuitry provides TTL logic input voltage level compatibility.
The DAC1208 series and DAC1230 series are the 12-bit members of a family of microprocessor compatible DACs (MICRO-DACs
TM
). For applications requiring other resolu­tions, the DAC1000 series for 10-bit and DAC0830 series for 8-bit are available alternatives.
Features
Y
Linearity specified with zero and full-scale adjust only
Y
Direct interface to all popular microprocessors
Y
Double-buffered, single-buffered or flow through digital data inputs
Y
Logic inputs which meet TTL voltage level specs (1.4V logic threshold)
Y
Works withg10V referenceÐfull 4-quadrant multiplication
Y
Operates stand-alone (without mP) if desired
Y
All parts guaranteed 12-bit monotonic
Y
DAC1230 series is pin compatible with the DAC0830 series 8-bit MICRO-DACs
Key Specifications
Y
Current Settling Time 1 ms
Y
Resolution 12 Bits
Y
Linearity (Guaranteed over temperature) 10, 11, or 12 Bits of FS
Y
Gain Tempco 1.3 ppm/§C
Y
Low Power Dissipation 20 mW
Y
Single Power Supply 5 VDCto 15 V
DC
Typical Application
TL/H/5690– 1
TRI-STATEÉis a registered trademark of National Semiconductor Corp. MICRO-DAC
TM
is a trademark of National Semiconductor Corp.
C
1995 National Semiconductor Corporation RRD-B30M115/Printed in U. S. A.
Absolute Maximum Ratings
If Military/Aerospace specified devices are required, please contact the National Semiconductor Sales Office/Distributors for availability and specifications.
(Notes 1 and 2)
Supply Voltage (V
CC
)17V
DC
Voltage at Any Digital Input VCCto GND
Voltage at V
REF
Input
g
25V
Storage Temperature Range
b
65§Ctoa150§C
Package Dissipation at T
A
e
25§C 500 mW
(Note 3)
DC Voltage Applied to I
OUT1
or I
OUT2
(Note 4)
b
100 mV to V
CC
ESD Susceptability 800V
Operating Conditions
Lead Temperature (Soldering, 10 sec.) 300§C
Temperature Range T
MIN
s
T
A
s
T
MAX
DAC1208LCJ, DAC1209LCJ, DAC1210LCJ, DAC1230LCJ, DAC1231LCJ, DAC1232LCJ, DAC1231LIN, DAC1232LIN
b
40§CsT
A
s
a
85§C DAC1208LCJ-1, DAC1210LCJ-1, DAC1230LCJ-1, DAC1231LCJ-1, DAC1232LCJ-1, DAC1231LCN, DAC1232LCN, DAC1231LCWM, DAC1232LCWM 0
§
CsT
A
s
a
70§C
Range of V
CC
4.75 VDCto 16 V
DC
Voltage at Any Digital Input VCCto GND
Electrical Characteristics
V
REF
e
10.000 VDC,V
CC
e
11.4 VDCto 15.75 VDCunless otherwise noted. Boldface limits apply from T
MIN
to T
MAX
(see
Note 13); all other limits T
A
e
T
J
e
25§C.
Typ
Tested Design
Parameter Conditions Notes
(Note 10)
Limit Limit Units
(Note 5) (Note 6)
Resolution 12 12 12 Bits
Linearity Error Zero and Full-Scale 4, 7, 13 (End Point Linearity) Adjusted
DAC1208, DAC1230
g
0.018g0.018 %ofFSR
DAC1209, DAC1231
g
0.024g0.024 %ofFSR
DAC1210, DAC1232
g
0.050g0.05 %ofFSR
Differential Non-Linearity Zero and Full-Scale 4, 7, 13
Adjusted DAC1208, DAC1230
g
0.018g0.018 %ofFSR
DAC1209, DAC1231
g
0.024g0.024 %ofFSR
DAC1210, DAC1232
g
0.050g0.05 %ofFSR
Monotonicity 4 12 12 12 Bits
Gain Error (Min) Using Internal R
Fb
7
b
0.1 0.0 % of FSR
Gain Error (Max)
V
ref
e
g
10V,g1V
7
b
0.1
b
0.2 % of FSR
Gain Error Tempco 7
g
1.3
g
6.0 ppm of FS/§C
Power Supply Rejection All Digital Inputs
7
g
3.0
g
30 ppm of FSR/V
Latched High
Reference Input Resistance (Min)
13
15 10 10
kX
Reference Input Resistance (Max) 15 20 20
Output Feedthrough Error V
REF
e
20 Vp-p, fe100 kHz All Data Inputs Latched 9 3.0 mVp-p Low
Output Capacitance All Data Inputs I
OUT1
200 pF
Latched High I
OUT2
70 pF
All Data Inputs I
OUT1
70 pF
Latched Low I
OUT2
200 pF
Supply Current Drain 13 2.0 2.5 mA
Output Leakage Current
I
OUT1
All Data Inputs Latched 11, 13 0.1 15 15 nA Low
I
OUT2
All Data Inputs Latched 11, 13 0.1 15 15 nA High
Digital Input Threshold Low Threshold 13 0.8 0.8 V
DC
High Threshold 13 2.2 2.2 V
DC
Digital Input Currents Digital Inputsk0.8V 13
b
200
b
200 mA
DC
Digital Inputsl2.2V 13 10 10 mA
DC
2
Electrical Characteristics (Continued)
V
REF
e
10.000 VDC,V
CC
e
11.4 VDCto 15.75 VDCunless otherwise noted. Boldface limits apply from T
MIN
to T
MAX
(see
Note 13); all other limits T
A
e
T
J
e
25§C.
See Typ
Tested Design
Symbol Parameter Conditions
Note (Note 10)
Limit Limit Units
(Note 5) (Note 6)
AC CHARACTERISTICS
t
s
Current Setting Time V
IL
e
0V, V
IH
e
5V 1.0 ms
t
W
Write and XFER V
IL
e
0V, V
IH
e
5V
8
50 320
Pulse Width Min. 320
t
DS
Data Setup Time Min. V
IL
e
0V, V
IH
e
5V 70 320
320
t
DH
Data Hold Time Min. V
IL
e
0V, V
IH
e
5V 30 90
ns
90
t
CS
Control Setup Time Min. V
IL
e
0V, V
IH
e
5V 60 320
320
t
CH
Control Hold Time Min. V
IL
e
0V, V
IH
e
5V 0 10
Note 1: Absolute Maximum Ratings indicate limits beyond which damage to the device may occur. DC and AC electrical specifications do not apply when operating the device beyond its specified operating conditions.
Note 2: All voltages are measured with respect to GND, unless otherwise specified.
Note 3: This 500 mW specification applies for all packages. The low intrinsic power dissipation of this part (and the fact that there is no way to significantly modify
the power dissipation) removes concern for heat sinking.
Note 4: Both I
OUT1
and I
OUT2
must go to ground or the virtual ground of an operational amplifier. The linearity error is degraded by approximately V
OS
d
V
REF
. For
example, if V
REF
e
10Vthena1mVoffset, VOS,onI
OUT1
or I
OUT2
will introduce an additional 0.01% linearity error.
Note 5: Tested and guaranteed to National’s AOQL (Average Outgoing Quality Level).
Note 6: Design limits are guaranteed but not 100% tested. These limits are not used to calculate outgoing quality levels. Guaranteed for V
CC
e
11.4V to 15.75V
and V
REF
eb
10V toa10V.
Note 7: The unit FSR stands for full-scale range. Linearity Error and Power Supply Rejection specs are based on this unit to eliminate dependence on a particular V
REF
value to indicate the true performance of the part. The Linearity Error specification of the DAC1208 is 0.012% of FSR(max). This guarantees that after
performing a zero and full-scale adjustment, the plot of the 4096 analog voltage outputs will each be within 0.012%
c
V
REF
of a straight line which passes through zero and full-scale. The unit ppm of FSR(parts per million of full-scale range) and ppm of FS(parts per million of full-scale) are used for convenience to define specs of very small percentage values, typical of higher accuracy converters. In this instance, 1 ppm of FSR
e
V
REF
/106is the conversion factor to provide an actual
output voltage quantity. For example, the gain error tempco spec of
g
6 ppm of FS/§C represents a worst-case full-scale gain error change with temperature from
b
40§Ctoa85§Cofg(6)(V
REF
/106)(125§C) org0.75 (10
b
3
)V
REF
which isg0.075% of V
REF
.
Note 8: This spec implies that all parts are guaranteed to operate with a write pulse or transfer pulse width (t
W
) of 320 ns. A typical part will operate with tWof only
100 ns. The entire write pulse must occur within the valid data interval for the specified t
W,tDS,tDH
and tSto apply.
Note 9: To achieve this low feedthrough in the D package, the user must ground the metal lid. If the lid is left floating the feedthrough is typically 6 mV.
Note 10: Typicals are at 25
§
C and represent the most likely parametric norm.
Note 11: A 10 nA leakage current with R
Fb
e
20k and V
REF
e
10V corresponds to a zero error of (10c10
b
9
c
20c103)c100% 10V or 0.002% of FS.
Note 12: Human body model, 100 pF discharged through a 1.5 kX resistor.
Note 13: Tested limit for
b
1 suffix parts applies only at 25§C.
Connection Diagrams
Dual-In-Line Package Dual-In-Line Package
TL/H/5690– 2
See Ordering Information
3
Switching Waveforms
TL/H/5690– 3
Typical Performance Characteristics
Digital Input Threshold vs V
CC
Digital Input Threshold vs Temperature
Gain and Linearity Error Variation vs Temperature
Gain and Linearity Error Variation vs Supply Voltage Control Set-Up Time, t
CS
Data Hold Time, t
DH
Write Pulse Width, t
W
Data Set-Up Time, t
DS
TL/H/5690– 4
4
Definition of Package Pinouts
CONTROL SIGNALS (all control signals are level actuated)
CS: Chip Select (active low). The CS will enable WR1.
WR1: Write 1. The active low WR1 is used to load the digital
data bits (DI) into the input latch. The data in the input latch is latched when WR1
is high. The 12-bit input latch is split into two latches. One holds the first 8 bits, while the other holds 4 bits. The Byte 1/Byte 2
control pin is used to select
both latches when Byte 1/Byte 2
is high or to overwrite the
4-bit input latch when in the low state.
Byte 1/Byte 2
: Byte Sequence Control. When this control is
high, all 12 locations of the input latch are enabled. When low, only the four least significant locations of the input latch are enabled.
WR2
: Write 2 (active low). The WR2 will enable XFER.
XFER: Transfer Control Signal (active low). This signal, in
combination with WR2
, causes the 12-bit data which is
available in the input latches to transfer to the DAC register.
DI
0
to DI11: Digital Inputs. DI0is the least significant digital
input (LSB) and DI
11
is the most significant digital input
(MSB).
I
OUT1
: DAC Current Output 1. I
OUT1
is a maximum for a digital code of all 1s in the DAC register, and is zero for all 0s in the DAC register.
I
OUT2
: DAC Current Output 2. I
OUT2
is a constant minus I
OUT1
,orI
OUT1
a
I
OUT2
e
constant (for a fixed reference
voltage). This constant current is
V
REF
c
#
1
b
1
4096
J
divided by the reference input resistance.
R
Fb
: Feedback Resistor. The feedback resistor is provided
on the IC chip for use as the shunt feedback resistor for the external op amp which is used to provide an output voltage for the DAC. This on-chip resistor should always be used (not an external resistor) since it matches the resistors in the on-chip R-2R ladder and tracks these resistors over temperature.
V
REF
: Reference Voltage Input. This input connects an ex-
ternal precision voltage source to the internal R-2R ladder. V
REF
can be selected over the range of 10V tob10V. This is also the analog voltage input for a 4-quadrant multiplying DAC application.
V
CC
: Digital Supply Voltage. This is the power supply pin for
the part. V
CC
can be from 5 VDCto 15 VDC. Operation is
optimum for 15 V
DC
.
GND: Pins 3 and 12 of the DAC1208, DAC1209, and DAC1210 must be connected to ground. Pins 3 and 10 of
the DAC1230, DAC1231, and DAC1232 must be connected to ground. It is important that I
OUT
1
and I
OUT
2
are at ground potential for current switching applications. Any difference of potential (V
OS
on these pins) will result in a linearity
change of
V
OS
3V
REF
For example, if V
REF
e
10V and these ground pins are 9
mV offset from I
OUT
1
and I
OUT
2
, the linearity change will be
0.03%.
Definition of Terms
Resolution: Resolution is defined as the reciprocal of the
number of discrete steps in the DAC output. It is directly related to the number of switches or bits within the DAC. For example, the DAC1208 has 2
12
or 4096 steps and therefore
has 12-bit resolution.
Linearity Error: Linearity error is the maximum deviation from a
straight line passing through the endpoints of the
DAC transfer characteristic
. It is measured after adjusting for zero and full-scale. Linearity error is a parameter intrinsic to the device and cannot be externally adjusted.
National’s linearity test (a) and the best straight line test (b) used by other suppliers are illustrated below. The best straight line (b) requires a special zero and FS adjustment for each part, which is almost impossible for the user to determine. The end point test uses a standard zero FS ad­justment procedure and is a much more stringent test for DAC linearity.
Power Supply Sensitivity: Power supply sensitivity is a measure of the effect of power supply changes on the DAC full-scale output.
Settling Time: Full-scale current settling time requires zero to full-scale or full-scale to zero output change. Settling time is the time required from a code transition until the DAC output reaches within
g
(/2 LSB of the final output value.
Full-Scale Error: Full-scale error is a measure of the output error between an ideal DAC and the actual device output. Ideally, for the DAC1208 or DAC1230 series, full-scale is V
REF
b
1 LSB. For V
REF
e
10V and unipolar operation,
V
FULL-SCALE
e
10.0000Vb2.44 mVe9.9976V. Full-scale
error is adjustable to zero.
Differential Non-Linearity: The difference between any two consecutive codes in the transfer curve from the theo­retical 1 LSB is differential non-linearity.
Monotonic: If the output of a DAC increases for increasing digital input code, then the DAC is monotonic. A 12-bit DAC which is monotonic to 12 bits simply means that input in­creasing digital input codes will produce an increasing ana­log output.
TL/H/5690– 5
a) End Point Test After Zero
and FS Adjust
b) Shifting FS Adjust to Pass
Best Straight Line Test
5
Application Hints
1.0 DIGITAL INTERFACE
These DACs are designed to provide all of the necessary digital input circuitry to permit a direct interface to a wide variety of microprocessor systems. The timing and logic lev­el convention of the input control signals allow the DACs to be treated as a typical memory device or I/O peripheral with no external logic required in most systems. Essentially these DACs can be mapped as a two-byte stack in memory (or I/O space) to receive their 12 bits of input data in two successive 8-bit data writing sequences. The DAC1230 se­ries is intended for use in systems with an 8-bit data bus. The DAC1208 series provides all 12 digital input lines which can be externally configured to be controlled from an 8-bit bus or can be driven directly from a 16-bit data bus.
All of the digital inputs to these DACs contain a unique threshold regulator circuit to maintain TTL voltage level compatibility independent of the applied V
CC
to the DAC. Any input can also be driven from higher voltage CMOS logic levels in non-microprocessor based systems. To pre­vent damage to the chip from static discharge, all unused digital inputs should be tied to V
CC
or ground. As a trouble­shooting aid, if any digital input is inadvertently left floating, the DAC will interpret the pin as a logic ‘‘1’’.
Double buffered digital inputs allow the DAC to internally format the 12-bit word used to set the current switching R­2R ladder network (see section 2.0) from two 8-bit data write cycles.
Figures 1
and2show the internal data regis­ters and their controlling logic circuitry. The timing diagrams for updating the DAC output are shown in sections 1.1, 1.2 and 1.3 for three possible control modes. The method used depends strictly upon the particular application.
FIGURE 1. DAC1208, DAC1209, DAC1210 Functional Diagram
TL/H/5690– 6
FIGURE 2. DAC1230, DAC1231, DAC1232 Functional Diagram
6
+ 12 hidden pages