SIPEX SP7514KN

®
HS3140/SP7514
14-Bit Multiplying DACs
■ Monolithic Construction
■ 14–Bit Resolution
■ 0.003% Non-Linearity
■ Four-Quadrant Multiplication
■ Latch-up Protected
■ Low Power - 30mW
■ Single +15V Power Supply
DESCRIPTION…
The SP7514 and HS3140 are precision 14-bit multiplying DACs, that provide four-quadrant
multiplication. Both parts accept both AC and DC reference voltages. The SP7514 is available
for use in commercial and industrial temperature ranges, packaged in a 20-pin SOIC. The
HS3140 is available in commercial and military temperature ranges, packaged in a 20-pin
side-brazed DIP.
V REF
15 EQUAL
SECTIONS
19
2
96k
96k
96k
I OUT2
96k
3
GND
VDD
SP7514,
HS3140
SP7514
48k
18
1
4 to 16 DECODE
4
5
6
BIT 1 BIT 2 BIT 3
(MSB)
HS3140/SP7514
I OUT1
6k
7
17
BIT 4
BIT 14
LSB
HS3140/SP7514 14-Bit Multiplying DACs
1
SWITCHES ARE
SHOWN IN THE
HIGH STATE
20
R FEEDBACK
© Copyright 2000 Sipex Corporation
SPECIFICATIONS
(Typical @ 25°C, nominal power supply, VREF = +10V, unipolar unless otherwise noted)
PARAMETER
DIGITAL INPUT
Resolution
2–Quad, Unipolar Coding
4–Quad, Bipolar Coding
Logic Compatibility
Input Current
REFERENCE INPUT
Voltage Range
Input Impedance
ANALOG OUTPUT
Scale Factor
Scale Factor Accuracy
Output Leakage
Output Capacitance
COUT 1, all inputs high
COUT 1, all inputs low
COUT 2, all inputs high
COUT 2, all inputs low
STATIC PERFORMANCE
Integral Linearity
SP7514KN/BN, HS3140–4
SP7514JN/AN, HS3140–3
Differential Linearity
SP7514KN/BN, HS3140–4
SP7514JN/AN, HS3140–3
Monotonicity
SP7514KN/BN, HS3140–4
SP7514JN/AN, HS3140–3
STABILITY
Scale Factor
Integral Linearity
Differential Linearity
Monotonicity Temp. Range
SP7514JN/KN, HS3140C
SP7514AN/BN
HS3140B
DYNAMIC PERFORMANCE
Digital Small Signal Settling
Digital Full Scale Settling
Reference Feedthrough Error
@ 1kHz
@ 10kHz
Reference Input Bandwidth
POWER SUPPLY (VDD)
Operating Voltage
Voltage Range
Current
Rejection Ratio
HS3140/SP7514
MIN.
TYP.
MAX.
14
UNITS
CONDITIONS
Bits
Binary
Offset Binary
CMOS, TTL
3.25
75
±1
µA
±25
9.75
V
KOhms
225
±1
10
µA/VREF
%
nA
100
50
50
100
Note 1
Note 2
Note 3
Note 4
pF
pF
pF
pF
Note 5
±0.003
±0.006
±0.006
±0.012
% FSR
% FSR
±0.003
±0.006
±0.006
±0.012
%FSR
% FSR
Note 6
Guaranteed to 14 bits
Guaranteed to 13 bits
4
0.5
0.5
0
–40
–55
1.0
1.0
ppm FSR/°C
ppm FSR/°C
ppm FSR/°C
°C
°C
°C
+70
+85
+125
1.0
2.0
µS
µS
200
2
1
µV
mV
MHz
+15 ±5%
+8
+18
2.0
0.005
V
V
mA
%/%
HS3140/SP7514 14-Bit Multiplying DACs
2
(TMIN to TMAX)
Note 7 and 8
(VREF = 20Vpp)
Note 9
© Copyright 2000 Sipex Corporation
SPECIFICATIONS (continued)
(Typical @ 25°C, nominal power supply, VREF = +10V, unipolar unless otherwise noted)
PARAMETER
MIN.
TYP.
MAX.
ENVIRONMENTAL AND MECHANICAL
Operating Temperature
SP7514JN/KN
0
+70
SP7514AN/BN
–40
+85
HS3140–C
0
+70
HS3140–B
–55
+125
HS3140–B/883
–55
+125
Storage Temperature
–65
+150
Package
SP7514_N
20-pin SOIC
HS3140
20–pin Side–Brazed DIP
UNITS
CONDITIONS
°C
°C
°C
°C
°C
°C
Notes:
1.
Digital input voltage must not exceed supply voltage or go below –0.5V ; “0” <0.8V; 2.4V < “1” ≤VDD.
2.
AC or DC; use R6758–1 for fixed reference applications
3.
Using the internal feedback resistor and an external op amp. The Scale Factor can be adjusted externally by variable resistors in series with the
reference input and/or in series to the internal feedback resistor. Please refer to the Applications Information section.
4.
At 25°C; the output leakage current will create an offset voltage at the external op amps output. It doubles every 10°C temperature increase.
5.
Integral Linearity is measured as the arithmetic mean value of the magnitudes of the greatest positive deviation and the greatest negative deviation from
the theoretical value for any given input combination.
6.
Differential Linearity is the deviation of an output step form the theoretical value of 1LSB for any two adjacent digital input codes.
7.
At 25°C, the output leakage current will create an offset voltage output. It doubles every 10°C temperature increase.
8.
Using the internal feedback resistor and an external op amp.
9.
Use series 470ohm resistor to limit start-up current.
CHARACTERISTIC CURVES
50
0.048
LINEARITY ERROR - PPM
INTEGRAL LINEARITY ERROR - %
(Typical @ + 25°C, VDD = + 15VDC, VREF = + 10VDC, unless otherwise noted)
0.024
0.012
0.006
0.003
40
2 LSB
30
20
1 LSB
10
0.01
0.1
1
1/2 LSB @ 16 BITS
10
V REF -VOLTS
0
Integral Linearity Error vs. Reference Voltage
0
10
20
LINEARITY - %
30
40
50
VOS-mV
0.048%
Additional Linearity Error vs. Output-Amplifier
Offset-Voltage (VREF = + 10V)
0.024%
0.01
0.012%
0.008
4
6
8
10
12
14
16
GAIN CHANGE - %
0.006%
0.003%
18
V DD -VOLTS
Linearity vs. Supply Voltage
2.5
0.004
0.002
2.0
I DD -mA
0.006
0
1.5
4
6
8
10
12
14
16
18
VDD -VOLTS
Gain Change vs. Supply Voltage
1.0
4
6
8
10
12
14
16
18
10
VDD -VOLTS
Power Supply Current vs. Voltage
HS3140/SP7514
HS3140/SP7514 14-Bit Multiplying DACs
3
© Copyright 2000 Sipex Corporation
PIN ASSIGNMENTS…
Pin 1 – IO1 – Current Output 1.
Pin 2 – IO2 – Current Output 2.
Pin 3 – GND – Ground.
Pin 4 – DB13 – MSB, Data Bit 1.
Pin 5 – DB12 – Data Bit 2.
Pin 6 – DB11 – Data Bit 3.
Pin 7 – DB10 – Data Bit 4.
Pin 8 – DB9 – Data Bit 5.
Pin 9 – DB8 – Data Bit 6.
Pin 10 – DB7 – Data Bit 7.
Pin 11 – DB6 – Data Bit 8.
Pin 12 – DB5 – Data Bit 9.
Pin 13 – DB4 – Data Bit 10.
Pin 14 – DB3 – Data Bit 11.
Pin 15 – DB2 – Data Bit 12.
Pin 16 – DB1 – Data Bit 13.
Pin 17 – DB0 – LSB, Data Bit 14.
Pin 18 – VDD – Positive Supply Voltage.
Pin 19 – VREF – Reference Voltage Input.
Pin 20 – RFB – Feedback Resistor.
PRINCIPLES OF OPERATION
The SP7514/HS3140 achieve high accuracy by using
a decoded or segmented DAC scheme to implement
this function. The following is a brief description of
this approach.
The most common technique for building a D/A
converter of n bits is to use n switches to turn n current
or voltage sources on or off. The n switches and n
sources are designed so that each switch or bit contributes twice as much to the D/A converter’s output as the
preceding bit. This technique is commonly known as
binary weighting and allows an n-bit converter to
generate 2n output levels by turning on the proper
combination of bits.
In such binary-weighted converter, the switch
with the smallest contribution (the LSB) accounts
for only 2-n of the converter’s full-scale value.
Similarly, the switch with the largest contribution
(the MSB) accounts for 2 -1 or half of the converter’s
full-scale output. Thus it is easy to see that a given
percent change in the MSB will have a greater
effect on the converter’s output than would a
similar percent change in the LSB. For example, a
1% change in the LSB of a 10 bit converter would
only affect the output by 0.001% of full-scale. A
1% change in the MSB of the same converter
would affect the output by 0.5% of FSR.
In order to overcome the problem which results from
the large weighting of the MSB, the two MSB’s can
be decoded to three equally weighted sources. Table
1 shows that all combinations of the two MSB’s of a
converter result in four output levels. So by replacing
the two MSB’s with three bits equally weighted at 1/
4 full-scale and decoding the two MSB digital inputs
into three lines which drive the equally weighted bits,
the same functional performance can be obtained.
Thus by replacing the two MSB switches of a conventional converter with three switches properly decoded, the contribution of any switch is reduced from
1/2 to 1/4. This reduction in sensitivity also reduces the
FEATURES…
The SP7514 and HS3140 are precision 14-bit multiplying DACs. The DACs are implemented as a onechip CMOS circuit with a resistor ladder network.
Three output lines are provided on the DACs to allow
unipolar and bipolar output connection with a minimum of external components. The feedback resistor
is internal. The resistor ladder network termination is
externally available, thus eliminating an external resistor for the 1 LSB offset in bipolar mode.
The SP7514 is available for use in commercial and
industrial temperature ranges, packaged in a 20-pin
SOIC. The HS3140 is available in commercial
and military temperature ranges, packaged in a
20–pin side–brazed DIP. For product processed
and screened to the requirements of MIL–M–
38510 and MIL–STD–883C, please consult the
factory (HS3140B only).
Cf
Rf
VREF
–
Ri
CO
Rp
+
EO
C
Figure 1. SP7514/HS3140 Equivalent Output Circuit
HS3140/SP7514
HS3140/SP7514 14-Bit Multiplying DACs
4
© Copyright 2000 Sipex Corporation
2 - 1(MSB)
0
0
1
1
2
Output
-2
0
1
0
1
470Ω
400Ω
V REF
0
1/4 Full-Scale
1/2 Full-Scale
3/4 Full-Scale
V DD
200Ω
RFEEDBACK
R OS
I O1
DIGITAL
INPUTS
Table 1. Contribution of the two MSB's
SP7514
HS3140
accuracy required of any switch for a given overall
converter accuracy.
A
I O2
+
GND
With the decoded converter described above, a 1%
change in any of the converter’s switches will affect
the output by no more than 0.25% of full-scale as
compared to 0.5% for a conventional converter. In
other words the conventional D/A converter can be
made less sensitive to the quality of its individual bits
by decoding.
Figure 2. Unipolar Operation
settling time, and bandwidth. The DAC output equivalent circuit can be represented as shown in Figure 1.
Digital feedthrough is the change in analog output due
to the toggling conditions on the converter input data
lines when the analog input VREF is at 0V. The
SP7514/HS3140 very low CO and therefore will yield
low digital feedthrough. Inputs to the DAC can be
buffered. This input latch with microprocessor control
is shown in Figure 4.
In the SP7514/HS3140 the first four MSB’s are
decoded into 16 levels which drive 15 equally weighted
current sources. The sensitivity of each switch on the
output is reduced by a factor of 8. Each of the 15
sources contributes 6.25% output change rather than
an MSB change of 50% for the common approach.
Settling time is directly affected by CO. In Figure 1, CO
combines with Rf to add a pole to the open loop
response, reducing bandwidth and causing excessive
phase shift - which could result in ringing and/or
oscillation. A feedback capacitor, Cf must be added to
restore stability. Even with Cf, there is still a zero-pole
mismatch due to RiCO which is code dependent. This
code dependent mismatch is minimized when CORi =
RfCf. However Cf must now be made larger to
compensate for worst case ∆RiCO - resulting in reduced bandwidth and increased settling time. With the
SP7514/HS3140, small values for Cf must be used.
Following the decoded section of the DAC a standard
binary weighted R-2R approach is used. This divides
each of the 16 levels (or 6.25% of F.S.) into 4096
discrete levels (the 12 LSB’s).
Output Capacitance
The SP7514/HS3140 have very low output capacitance (CO). This is specified both with all switches ON
and all switches OFF. Output capacitance varies from
50pF to 100pF over all input codes. This low capacitance is due in part to the decoding technique used.
Smaller switches are used with resulting less capacitance. Three important system characteristics are
affected by CO and ∆CO; namely digital feedthrough,
470Ω
400Ω
V REF
V DD
200Ω
R FEEDBACK
R OS1
I O1
TRANSFER FUNCTION (N=14)
DIGITAL
INPUTS
A1
+
SP7514
HS3140
BINARY INPUT UNIPOLAR OUTPUT BIPOLAR OUTPUT
111...111
–VREF (1 - 2–N)
100...001
–VREF (1/2 + 2 )
100...000
–VREF /2
0
011...111
–VREF (1/2 – 2–N)
VREF (2 –(N – 1))
000…001
000...000
–N
–VREF (2
0
)
(N – 1)
4KΩ
I O2
)
–(N – 1)
R OS2
R
GND
R OS2
A2
+
VREF (1 – 2 –(N – 1))
V OUT1
A1, A2 , OP-07
VREF
Table 2. Transfer Function
HS3140/SP7514
V OUT
4KΩ
–VREF (1 – 2 –(N – 1))
–VREF (2
V OUT
Figure 3. Bipolar Operation
HS3140/SP7514 14-Bit Multiplying DACs
5
© Copyright 2000 Sipex Corporation
400
D0
D0
D1
D1
D2
D2
D3
D3
74273
D4
D4
D5
D5
D6
D6
D7
D7
CLK
D0
D1
D2
WR
G2A
74273
BDSEL
A2
D5
G2B
C
A1
B
A0
A
ADDRESS DECODER
D3
D4
74LS138
D6
CLK
1. Using LF441A amplifier (low power - 741 pinout)
2. Specified offset: 0.5mV max
3. Temperature coefficient of input offset: 10µV/°C max
VOS max (0°C to 70°C) = 0.5mV + (70µV)10
= 1.2mV
Add'l nonlinearity (max.) = 1.2mV x 0.065mV/mV
=
78µV (1/2 LSB @ 16 Bits)
Where: 78µV = 1/2 LSB @ 16 Bits (10V range)
V DD
VREF
(+ 25V MAX)
D7
470 3
LSB VREF
15 + VDD
14
13
UNIPOLAR MODE
(2-QUADRANT)
200
RF
12
11
10
I 01
9
I 02
SP7514/
SP7514/
7516
HS3140
8
2
–
A
3 +1
6
VOUT
0 TO - V REF
(1-2 - N)
R 0S
7
6
5
4
3
Via the above configuration, the SP7514/HS3140
can be used to divide an analog signal by digital code
(i.e. for digitally controlled gain). The transfer function is given in Table 2, where the value of each bit is
0 or 1. Division by all “0”s is undefined and causes the
op amp to saturate.
2
MSB GND
LATCHES
Figure 4. Microprocessor Interface to SP7514/HS3140
Resistor Rp can be added, this will parallel Rj decreasing the effective resistance. If Cf is reduced the
bandwidth will be increased and settling time decreased. However a system penalty for lowering Cf is
to increase noise gain. The trade-off is noise vs.
settling time. If Rp is added then a large value (1µF or
greater) non-polarized capacitor Cp should be added
in series with Rp to eliminate any DC drifts. If settling
time is not important, eliminate Rp and Cp, and adjust
Cf to prevent overshoot.
Applications Information
Unipolar Operation
Figure 2 shows the interconnections for unipolar
operation. Connect IO1 and FB1 as shown in diagram.
Tie IO2 (Pin 7), FB3 (Pin 3), and FB4 (Pin 1) to Ground
(Pin 8). As shown, a series resistor is recommended in
the VDD supply line to limit current during ‘turn-on’.
To maintain specified linearity, external amplifiers
must be zeroed. Apply an ALL “ZEROES” digital
input and adjust ROS for VOUT = 0 ± 1mV. The
SP7514 and HS3140 have been used successfully
with OP-07, OP-27 and LF441A. For high speed
applications the SP2525 is recommended.
Output Offset
In most applications, the output of the DAC is fed into
an amplifier to convert the DAC’s current output to
voltage. A little known and not commonly discussed
parameter is the linearity error versus offset voltage of
the output amplifier. All CMOS DAC’s must operate
into a virtual ground, i.e., the summing junction of an
op amp. Any amplifier’s offset from the amplifier will
appear as an error at the output (which can be related
to LSB’s of error).
Bipolar Operation
Figure 3 shows the interconnections for bipolar operation. Connect IO1, IO2, FB1, FB3, FB4 as shown in
diagram. Tie LDTR to IO2. As shown, a series resistor
is recommended in the VDD supply line to limit current
during ‘turn-on. To maintain specified linearity, external amplifiers must be zeroed. This is best done with
VREF set to zero and, the DAC register loaded with
10...0 (MSB = 1). Set R0S1 for V01 = 0. Set R0S2 for
VOUT = 0. Set VREF to +10V and adjust RB for VOUT
to be 0V.
Most all CMOS DAC’s currently available are implemented using an R-2R ladder network. The formula
for nonlinearity is typically 0.67mV/mVOS (not derived here). However the SP7516 has a coefficient of
only 0.065mV/mVOS. This is due to the decoding
technique described earlier. CMOS DAC applications notes (including this one) always show a potentiometer used to null out the amplifier’s offset. If an
amplifier is chosen having ‘pretrimmed’ offset it may
be possible to eliminate this component. Consider the
following calculations:
HS3140/SP7514
Grounding
Connect all GND pins to system analog ground
and tie this to digital ground. All unused input pins
must be grounded.
HS3140/SP7514 14-Bit Multiplying DACs
6
© Copyright 2000 Sipex Corporation
ORDERING INFORMATION
Model ................................................................ Monotonicity .................................. Temperature Range .................................... Package
Double-Buffered 12-Bit Multiplying DAC
HS3140C-3Q ............................................................ 13-Bit ............................................... 0°C to +70°C ................... 20-pin, 0.3" Side-Brazed
HS3140B-3Q ............................................................ 13-Bit ......................................... -55°C to +125°C ................... 20-pin, 0.3" Side-Brazed
HS3140B-3/883 ....................................................... 13-Bit ......................................... -55°C to +125°C ................... 20-pin, 0.3" Side-Brazed
HS3140C-4Q ............................................................ 14-Bit ............................................... 0°C to +70°C ................... 20-pin, 0.3" Side-Brazed
HS3140B-4Q ............................................................ 14-Bit ......................................... -55°C to +125°C ................... 20-pin, 0.3" Side-Brazed
HS3140B-4/883 ....................................................... 14-Bit ......................................... -55°C to +125°C ................... 20-pin, 0.3" Side-Brazed
SP7514JN ................................................................
SP7514KN ...............................................................
SP7514AN ...............................................................
SP7514BN ...............................................................
13-Bit ............................................... 0°C
14-Bit ............................................... 0°C
13-Bit .......................................... –40°C
14-Bit .......................................... –40°C
to
to
to
to
+70°C
+70°C
+85°C
+85°C
...................................... 20-pin,
...................................... 20-pin,
...................................... 20-pin,
...................................... 20-pin,
0.3"
0.3"
0.3"
0.3"
DIP
DIP
DIP
DIP
DIP
DIP
SOIC
SOIC
SOIC
SOIC
Corporation
SIGNAL PROCESSING EXCELLENCE
Sipex Corporation
Headquarters and
Sales Office
22 Linnell Circle
Billerica, MA 01821
TEL: (978) 667-8700
FAX: (978) 670-9001
e-mail: [email protected]
Sales Office
233 South Hillview Drive
Milpitas, CA 95035
TEL: (408) 934-7500
FAX: (408) 935-7600
Sipex Corporation reserves the right to make changes to any products described herein. Sipex does not assume any liability arising out of the
application or use of any product or circuit described hereing; neither does it convey any license under its patent rights nor the rights of others.
HS3140/SP7514
HS3140/SP7514 14-Bit Multiplying DACs
7
© Copyright 2000 Sipex Corporation