AD AD783JRZ

AD783–SPECIFICATIONS
DC SPECIFICATIONS
(TMIN to TMAX with VCC = +5 V 6 5%, VEE = –5 V 6 5%, CL = pF, unless otherwise noted)
Parameter
Min
SAMPLING CHARACTERISTICS
Acquisition Time
5 V Step to 0.01%
5 V Step to 0.1%
Small Signal Bandwidth
Full Power Bandwidth
HOLD CHARACTERISTICS
Effective Aperture Delay (+25°C)
Aperture Jitter (+25°C)
Hold Settling (to 1 mV, +25°C)
Droop Rate
Feedthrough (+25°C)
(VIN = ± 2.5 V, 500 kHz)
–30
AD783J/A
Typ
Max
Units
250
200
15
2
375
350
ns
ns
MHz
MHz
15
20
150
0.02
30
50
200
1
ns
ps
ns
µV/µs
–80
dB
1
ACCURACY CHARACTERISTICS
Hold Mode Offset
Hold Mode Offset Drift
Sample Mode Offset
Nonlinearity
Gain Error
OUTPUT CHARACTERISTICS
Output Drive Current
Output Resistance, DC
Total Output Noise (DC to 5 MHz)
Sampled DC Uncertainty
Hold Mode Noise (DC to 5 MHz)
Short Circuit Current
Source
Sink
INPUT CHARACTERISTICS
Input Voltage Range
Bias Current
Input Impedance
Input Capacitance
DIGITAL CHARACTERISTICS
Input Voltage Low
Input Voltage High
Input Current High (VIN = 5 V)
POWER SUPPLY CHARACTERISTICS
Operating Voltage Range
Supply Current
+PSRR (+5 V ± 5%)
–PSRR (–5 V ± 5%)
Power Consumption
TEMPERATURE RANGE
Specified Performance (J)
Specified Performance (A)
–5
0
10
50
± 0.005
± 0.03
–5
0.3
150
85
125
–2.5
100
10
2
+5
200
± 0.1
+5
0.6
mA
Ω
µV rms
µV rms
µV rms
20
13
mA
mA
+2.5
250
V
nA
MΩ
pF
0.8
V
V
µA
2.0
± 4.75
45
45
0
–40
mV
µV/°C
mV
% FS
% FS
2
10
±5
9.5
65
65
95
± 5.25
17
175
V
mA
dB
dB
mW
+70
+85
°C
°C
NOTES
1
Specified and tested over an input range of ± 2.5 V.
Specifications subject to change without notice.
–2–
REV. A
AD783
HOLD MODE AC SPECIFICATIONS (T
MIN to TMAX with VCC = +5 V 6 5%, VEE = –5 V 6 5%, CL = 50 pF, unless
Parameter
AD783J/A
Typ
Min
otherwise noted)
Max
Units
–80
dB
dB
TOTAL HARMONIC DISTORTION
fIN = 100 kHz
fIN = 500 kHz
–85
–72
SIGNAL-TO-NOISE AND DISTORTION
fIN = 100 kHz
fIN = 500 kHz
77
70
dB
dB
INTERMODULATION DISTORTION
(F1 = 99 kHz, F2 = 100 kHz)
Second Order Products
Third Order Products
–80
–85
dB
dB
NOTES
1
fIN amplitude = 0 dB and f SAMPLE = 300 kHz unless otherwise indicated.
Specifications subject to change without notice.
ABSOLUTE MAXIMUM RATINGS*
Spec
VCC
VEE
Analog Input
Digital Input
Output Short Circuit to
Ground, VCC, or VEE
Maximum Junction
Temperature
Storage
Lead Temperature
(10 sec max)
PIN CONFIGURATION
With
Respect to
Min
Max
Units
COM
COM
COM
COM
–0.5
–6.5
–6.5
–0.5
+6.5
+0.5
+6.5
+6.5
V
V
V
V
VCC
1
IN
2
COMMON
3
NC
4
Indefinite
–65
8
OUT
AD783
7
S/H
TOP VIEW
(Not to Scale)
6
NC
5
VEE
NC = NO CONNECT
+175 °C
+150 °C
+300 °C
*Stresses above those listed under “Absolute Maximum Ratings” may cause
permanent damage to the device. This is a stress rating only and functional
operation of the device at these or any other conditions above those indicated in the
operational section of this specification is not implied.
CAUTION
ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000 V readily
accumulate on the human body and test equipment and can discharge without detection.
Although the AD783 features proprietary ESD protection circuitry, permanent damage may
occur on devices subjected to high energy electrostatic discharges. Therefore, proper ESD
precautions are recommended to avoid performance degradation or loss of functionality.
WARNING!
ESD SENSITIVE DEVICE
ORDERING GUIDE
Model1
Temperature
Range
Description
Package
Options2
AD783JQ
AD783AQ
AD783JR
AD783AR
0°C to +70°C
–40°C to +85°C
0°C to +70°C
–40°C to +85°C
8-Pin Cerdip
8-Pin Cerdip
8-Pin SOIC
8-Pin SOIC
Q-8
Q-8
R-8
R-8
NOTES
1
For details on grade and package offerings screened in accordance with MIL-STD-883, refer to the
1
Analog Devices Military Products Databook or current AD783/883B data sheet.
2
Q = Cerdip, R = SOIC.
REV. A
–3–
AD783–Typical Characteristics
10.0
V+
60
V–
DROOP RATE – µV/µs
1.0
PSRR – dB
50
40
0.1
0.01
30
0.001
0
1
10
100
1k
10k
100k
0
1M
25
50
75
100
TEMPERATURE – °C
FREQUENCY – Hz
Power Supply Rejection Ratio vs. Frequency
125
150
Droop Rate vs. Temperature, VIN = 0 V
200
ACQUISITION TIME – ns
150
BIAS CURRENT – nA
100
50
0
–50
–100
300
250
200
–150
0
–200
–2.5
0
INPUT VOLTAGE – V
0
+2.5
1
2
3
INPUT STEP – V
4
5
Acquisition Time (to 0.01%) vs. Input Step Size
Bias Current vs. Input Voltage
–4–
REV. A
AD783
Output Drive Current—The maximum current the SHA can
source (or sink) while maintaining a change in hold mode offset
of less than 2.5 mV.
DEFINITIONS OF SPECIFICATIONS
Acquisition Time—The length of time that the SHA must
remain in the sample mode in order to acquire a full-scale input
step to a given level of accuracy.
Signal-To-Noise and Distortion (S/N+D) Ratio—S/N+D is
the ratio of the rms value of the measured input signal to the
rms sum of all other spectral components below the Nyquist
frequency, including harmonics but excluding dc. The value for
S/N+D is expressed in decibels.
Small Signal Bandwidth—The frequency at which the held
output amplitude is 3 dB below the input amplitude, under an
input condition of a 100 mV p-p sine wave.
Full Power Bandwidth—The frequency at which the held
output amplitude is 3 dB below the input amplitude, under an
input condition of a 5 V p-p sine wave.
Total Harmonic Distortion (THD)—THD is the ratio of the
rms sum of the first six harmonic components to the rms value
of the measured input signal and is expressed in decibels.
Effective Aperture Delay—The difference between the switch
delay and the analog delay of the SHA channel. A negative
number indicates that the analog portion of the overall delay is
greater than the switch portion. This effective delay represents
the point in time, relative to the hold command, that the input
signal will be sampled.
Hold Settling Time—The time required for the output to
settle to within a specified level of accuracy of its final held value
after the hold command has been given.
Intermodulation Distortion (IMD)—With inputs consisting
of sine waves at two frequencies, fa and fb, any device with
nonlinearities will create distortion products, of order (m+n), at
sum and difference frequency of mfa± nfb, where m, n = 0, 1, 2,
3. . . . Intermodulation terms are those for which m or n is not
equal to zero. For example, the second order terms are (fa+fb)
and (fa–fb), and the third order terms are (2fa+fb), (2fa–fb),
(fa+2fb) and (fa–2fb). The IMD products are expressed as the
decibel ratio of the rms sum of the measured input signals to the
rms sum of the distortion terms. The two signals are of equal
amplitude, and peak value of their sums is –0.5 dB from full
scale. The IMD products are normalized to a 0 dB input signal.
Droop Rate—The drift in output voltage while in the hold
mode.
FUNCTIONAL DESCRIPTION
Aperture Jitter—The variations in aperture delay for
successive samples. Aperture jitter puts an upper limit on the
maximum frequency that can be accurately sampled.
The AD783 is a complete, high speed sample-and-hold
amplifier that provides high speed sampling to 12-bit accuracy
in 250 ns.
Feedthrough—The attenuated version of a changing input
signal that appears at the output when the SHA is in the hold
mode.
The AD783 is completely self-contained, including an on-chip
hold capacitor, and requires no external components or adjustments to perform the sampling function. Both input and output
are treated as a single-ended signal, referred to common.
Hold Mode Offset—The difference between the input signal
and the held output. This offset term applies only in the hold
mode and includes the error caused by charge injection and all
other internal offsets. It is specified for an input of 0 V.
The AD783 utilizes a proprietary circuit design which includes a
self-correcting architecture. This sample-and-hold circuit
corrects for internal errors after the hold command has been
given, by compensating for amplifier gain and offset errors, and
charge injection errors. Due to the nature of the design, the
SHA output in the sample mode is not intended to provide an
accurate representation of the input. However, in hold mode,
the internal circuitry is reconfigured to produce an accurately
held version of the input signal. Below is a block diagram of the
AD783.
Sample Mode Offset—The difference between the input and
output signals when the SHA is in the sample mode.
Nonlinearity—The deviation from a straight line on a plot of
input vs. (held) output as referenced to a straight line drawn
between endpoints, over an input range of –2.5 V and +2.5 V.
Gain Error—Deviation from a gain of +1 on the transfer
function of input vs. held output.
Power Supply Rejection Ratio—A measure of change in the
held output voltage for a specified change in the positive or
negative supply.
Sampled DC Uncertainty—The internal rms SHA noise that
is sampled onto the hold capacitor.
Hold Mode Noise—The rms noise at the output of the SHA
while in the hold mode, specified over a given bandwidth.
VCC
1
IN
2
OUT
7
S/H
6
NC
5
VEE
X1
Total Output Noise—The total rms noise that is seen at the
output of the SHA while in the hold mode. It is the rms
summation of the sampled dc uncertainty and the hold mode
noise.
COMMON
3
NC
4
AD783
NC = NO CONNECT
Functional Block Diagram
REV. A
8
–5–
AD783
DYNAMIC PERFORMANCE
(VOUT HOLD – VIN ), mV
VOUT ACQUISITION ACCURACY – %
The AD783 is compatible with 12-bit A-to-D converters in
terms of both accuracy and speed. The fast acquisition time, fast
hold settling time and good output drive capability allow the
AD783 to be used with high speed, high resolution A-to-D
converters like the AD671 and AD7586. The AD783’s fast
acquisition time provides high throughput rates for multichannel
data acquisition systems. Typically, the AD783 can acquire a
5 V step in less than 250 ns. Figure 1 shows the settling
accuracy as a function of acquisition time.
+1
V IN , VOLTS
–2.5
+2.5
NONLINEARITY
0.08
–1
GAIN ERROR
0.06
HOLD MODE OFFSET
0.04
Figure 2. Hold Mode Offset, Gain Error and Nonlinearity
For applications where it is important to obtain zero offset, the
hold mode offset may be nulled externally at the input to the
A-to-D converter. Adjustment of the offset may be accomplished through the A-to-D itself or by an external amplifier
with offset nulling capability (e.g., AD711). The offset will
change less than 0.5 mV over the specified temperature range.
0.02
0
0
250
500
ACQUISITION TIME – ns
Figure 1. VOUT Settling vs. Acquisition Time
The hold settling determines the required time, after the hold
command is given, for the output to settle to its final specified
accuracy. The typical settling behavior of the AD783 is 150 ns.
The settling time of the AD783 is sufficiently fast to allow the
SHA, in most cases, to directly drive an A-to-D converter
without the need for an added “start convert” delay.
SUPPLY DECOUPLING AND GROUNDING
CONSIDERATIONS
As with any high speed, high resolution data acquisition system,
the power supplies should be well regulated and free from
excessive high frequency noise (ripple). The supply connection
to the AD783 should also be capable of delivering transient
currents to the device. To achieve the specified accuracy and
dynamic performance, decoupling capacitors must be placed
directly at both the positive and negative supply pins to common. Ceramic type 0.1 µF capacitors should be connected from
VCC and VEE to common.
HOLD MODE OFFSET
The dc accuracy of the AD783 is determined primarily by the
hold mode offset. The hold mode offset refers to the difference
between the final held output voltage and the input signal at the
time the hold command is given. The hold mode offset arises
from a voltage error introduced onto the hold capacitor by
charge injection of the internal switches. The nominal hold
mode offset is specified for a 0 V input condition. Over the input range of –2.5 V to +2.5 V, the AD783 is also characterized
for an effective gain error and nonlinearity of the held value, as
shown in Figure 2. As indicated by the AD783 specifications,
the hold mode offset is very stable over temperature.
ANALOG
P.S.
+5V
C
0.1µF
DIGITAL
P.S.
–5V
0.1µF
C
1µF
1µF
+5V
1µF
INPUT
AD783
ANALOG-TO-DIGITAL
CONVERTER
DIGITAL
DATA
OUTPUT
SIGNAL GROUND
Figure 3. Basic Grounding and Decoupling Diagram
–6–
REV. A
AD783
The accuracy in sampling high frequency signals is also
constrained by the distortion and noise created by the
sample-and-hold. The level of distortion increases with
frequency and reduces the “effective number of bits” of the
conversion.
The AD783 does not provide separate analog and digital ground
leads as is the case with most A-to-D converters. The common
pin is the single ground terminal for the device. It is the reference point for the sampled input voltage and the held output
voltage and also the digital ground return path. The common
pin should be connected to the reference (analog) ground of the
A-to-D converter with a separate ground lead. Since the analog
and digital grounds in the AD783 are connected internally, the
common pin should also be connected to the digital ground,
which is usually tied to analog common at the A-to-D converter.
Figure 3 illustrates the recommended decoupling and grounding
practice.
Measurements of Figures 6 and 7 were made using a 14-bit
A/D converter with VIN = 5 V p-p and a sample frequency of
100 kSPS.
1%
1/2 BIT @
8 BITS
NOISE CHARACTERISTICS
Designers of data conversion circuits must also consider the
effect of noise sources on the accuracy of the data acquisition
system. A sample-and-hold amplifier that precedes the A-to-D
converter introduces some noise and represents another source
of uncertainty in the conversion process. The noise from the
AD783 is specified as the total output noise, which includes
both the sampled wideband noise of the SHA in addition to the
band limited output noise. The total output noise is the rms
sum of the sampled dc uncertainty and the hold mode noise. A
plot of the total output noise vs. the equivalent input bandwidth
of the converter being used is given in Figure 4.
0.1%
1/2 BIT @
10 BITS
1/2 BIT @
12 BITS
APERTURE JITTER TYPICAL AT 20ps
0.01%
1/2 BIT @
14 BITS
1k
10k
1M
100k
FREQUENCY – Hz
Figure 5. Error Magnitude vs. Frequency
300
–70
200
–75
THD – dB
OUTPUT NOISE – µV rms
–65
100
–80
–85
–90
0
1k
10k
100k
1M
10M
FREQUENCY – Hz
–95
100
Figure 4. RMS Noise vs. Input Bandwidth of ADC
1k
100k
10k
1M
FREQUENCY – Hz
DRIVING THE ANALOG INPUTS
Figure 6. Total Harmonic Distortion vs. Frequency
For best performance, it is important to drive the AD783 analog
input from a low impedance signal source. This enhances the
sampling accuracy by minimizing the analog and digital crosstalk. Signals which come from higher impedance sources (e.g.,
over 5 kΩ) will have a relatively higher level of crosstalk. For
applications where signals have high source impedance, an
operational amplifier buffer in front of the AD783 is required.
The AD711 (precision BiFET op amp) is recommended for
these applications.
90
80
S/(N + D) – dB
70
HIGH FREQUENCY SAMPLING
Aperture jitter and distortion are the primary factors which limit
frequency domain performance of a sample-and-hold amplifier.
Aperture jitter modulates the phase of the hold command and
produces an effective noise on the sampled analog input. The
magnitude of the jitter induced noise is directly related to the
frequency of the input signal.
50
40
30
20
10
0
1k
10k
100k
1M
FREQUENCY – Hz
A graph showing the magnitude of the jitter induced error vs.
frequency of the input signal is given in Figure 5.
REV. A
60
Figure 7. Signal/(Noise and Distortion) vs. Frequency
–7–
AD783 TO AD670 INTERFACE
The 15 MHz small signal bandwidth of the AD783 makes it a
good choice for undersampling applications. Figure 8 shows
the interface between the AD783 and the AD670 ADC, where
the AD783 samples the incoming IF signal. For this particular
application, the IF carrier was 10.7 MHz and the information
signal was a 5 kHz FSK-modulated tone. The sample-and-hold
signal is applied to the 8-bit AD670 ADC and then digitally
processed for analysis.
The CLKIN signal is connected directly to the S/H pin of the
AD783 and must comply with the acquisition and settling requirements of the SHA. A delayed version of CLKIN is applied
to the R/W input of the AD670 in order to accommodate the
hold-mode settling requirements of the AD783. The 10 µs conversion speed of the AD670 combined with the 150 ns holdmode settling time of the AD783 result in a total system
throughput of 10.15 µs.
The low going one-shot output is connected to the clock input
of flip-flop2. The D2 input of flip-flop2 is tied high. The rising
edge of the low going pulse toggles the Q2 output of flip-flop2 to
a high state. This output, which is tied to the ENCODE input of
the AD671, initiates a conversion of the buffered output signal
of the AD783. The AD671 issues the signal DAV when the conversion is complete. The DAV signal is tied to the asynchronous
CLR1 and CLR2 inputs of both flip-flops. When DAV goes low,
the Q1 output goes high returning the AD783 to the sample or
acquisition mode. The Q2 output (ENCODE) returns low until
it is again triggered by the rising edge of the one-shot output.
VIN
AD783
50
10.7MHz
255mV p-p
AD783
8
AD671
Q1
+5V
CLR1
CLR2
ONESHOT
OUTLINE DIMENSIONS
Dimensions shown in inches and (mm).
8-Pin Cerdip (Q-8) Package
18 +VIN HI
8
5
0.310 (7.87)
0.220 (5.59)
16 –VIN HI
17 –VIN LOW
4
1
AD670
ONE SHOT
ENCODE
Figure 9. AD783 to AD671 Interface
19 +VIN LOW
CLK IN
DAV
Q2
10k
7
D1
D2
0.405 (10.29)
MAX
21 R/W
0.200
(5.08)
MAX
Figure 8. AD783 to AD670 Interface
0.150
(3.81)
MIN
AD783 to AD671 (12-Bit, 500 ns ADC) Interface
The AD783 to AD671 interface requires an op amp, a dual
flip-flop, and a monostable multivibrator or “one-shot.” The
op amp amplifies the ± 2.5 V output of the AD783 to the
full-scale input of the AD671. Appropriate op amps include the
AD841 and AD845 (see the AD671 data sheet for additional
information). The flip-flops and one-shot are used to generate
the AD671 ENCODE pulse and the appropriately timed
AD783 S/H pulse.
0.320 (8.13)
0.290 (7.37)
0.060 (1.52)
0.015 (0.38)
0.023 (0.58)
0.014 (0.36)
0.015 (0.381)
0.008 (0.204)
0.100 (2.54)
BSC
0.070 (1.78)
0.030 (0.76)
8-Pin SOIC (R-8) Package
PRINTED IN U.S.A.
2
AIN
AD84X
CLOCK
By keeping the 10.7 MHz IF input to the AD783 at a low
amplitude, 255 mV p-p, the resultant distortion and jitterinduced noise result in approximately 45 dB of dynamic range.
The AD670 can be conveniently configured such that its fullscale input range is 255 mV in order to retain the full 8-bit
dynamic range of the converter. The maximum sample rate of
the AD670 is 10 µs; therefore, to comply with the Nyquist
criteria the maximum information bandwidth is 50 kHz.
ANALOG
INPUT
C1733–12–10/92
AD783
0.198 (5.03)
0.188 (4.77)
A master sampling clock is tied to the clock input of flip-flop1
and the input of the one-shot. The D1 input of flip-flop1
should be tied high and the one-shot should be configured to
generate a pulse on a rising edge of the sampling clock. The rising edge of the sampling clock causes the Q1 output of the
flip-flop to go low placing the AD783 into hold mode. Simultaneously, a low going pulse is generated at the one-shot output.
The length of this pulse would usually be made long enough to
allow the output of the AD783 to settle (hold-mode settling
time), but because of the error-correcting ability of the AD671,
the length of this pulse may be reduced to approximately 200 ns.
8
5
0.158 (4.01)
0.150 (3.81)
1
0.050 (1.27)
BSC
0.248 (6.29)
0.224 (5.69)
4
0.022 (0.56)
0.014 (0.36)
0.205 (5.21)
0.195 (4.95)
0.107 (2.72)
0.011 (0.275)
0.005 (0.125)
–8–
0.089 (2.26)
0.015 (0.38)
0.007 (0.18)
0.034 (0.86)
0.018 (0.46)
REV. A