AD AD775JN

a
FUNCTIONAL BLOCK DIAGRAM
V IN
AV DD
18
14
15
SWITCH
MATRIX
FINE COMPARATORS
BANK A
23
FINE COMPARATORS
BANK B
V RBS 22
5
CLOCK LOGIC
AV SS
20
21
AV SS
12
CLK
2
8
3-STATE OUTPUT LATCHES
CORRECTION LOGIC
17
255
V RB
10 D7 (MSB)
4
COARSE
COMPARATORS
LSB MULTIPLEXOR
V RT
11
13
AD775
15
VRTS 16
DV DD
19
AV DD
RREF
FEATURES
CMOS 8-Bit 20 MSPS Sampling A/D Converter
Low Power Dissipation: 60 mW
+5 V Single Supply Operation
Differential Nonlinearity: 0.3 LSB
Differential Gain: 1%
Differential Phase: 0.5 Degrees
Three-State Outputs
On-Chip Reference Bias Resistors
Adjustable Reference Input
Video Industry Standard Pinout
Small Packages:
24-Pin 300 Mil SOIC Surface Mount
24-Pin 400 Mil Plastic DIP
8-Bit 20 MSPS, 60 mW
Sampling A/D Converter
AD775
9
8
7
6
5
4
3
D0 (LSB)
1
OE
24
DV SS
PRODUCT DESCRIPTION
PRODUCT HIGHLIGHTS
The AD775 is a CMOS, low power, 8-bit, 20 MSPS sampling
analog-to-digital converter (ADC). The AD775 features a builtin sampling function and on-chip reference bias resistors to provide a complete 8-bit ADC solution. The AD775 utilizes a
pipelined/ping pong two-step flash architecture to provide high
sampling rates (up to 35 MHz) while maintaining very low
power consumption (60 mW).
Low Power: The AD775 has a typical supply current of 12 mA,
for a power consumption of 60 mW. Reference ladder current
is also low: 6.6 mA typical, minimizing the reference power
consumption.
Its combination of excellent DNL, fast sampling rate, low differential gain and phase errors, extremely low power dissipation,
and single +5 V supply operation make it ideally suited for a
variety of video and image acquisition applications, including
portable equipment. The AD775’s reference ladder may be connected in a variety of configurations to accommodate different
input ranges. The low input capacitance (11 pF typical) provides
an easy-to-drive input load compared to conventional flash
converters.
The AD775 is offered in both 300 mil SOIC and 400 mil DIP
plastic packages, and is designed to operate over an extended
commercial temperature range (–20°C to +75°C).
Complete Solution: The AD775’s switched capacitor design
features an inherent sample/hold function: no external SHA is
required. On-chip reference bias resistors are included to allow
a supply-based reference to be generated without any external
resistors.
Excellent Differential Nonlinearity: The AD775 features a
typical DNL of 0.3 LSBs, with a maximum limit of 0.5 LSBs.
No missing codes is guaranteed.
Single +5 V Supply Operation: The AD775 is designed to operate on a single +5 V supply, and the reference ladder may be
configured to accommodate analog inputs inclusive of ground.
Low Input Capacitance: The 11 pF input capacitance of the
AD775 can significantly decrease the cost and complexity of
input driving circuitry, compared with conventional 8-bit flash
ADCs.
REV. 0
Information furnished by Analog Devices is believed to be accurate and
reliable. However, no responsibility is assumed by Analog Devices for its
use, nor for any infringements of patents or other rights of third parties
which may result from its use. No license is granted by implication or
otherwise under any patent or patent rights of Analog Devices.
One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 617/329-4700
Fax: 617/326-8703
(T = +258C with AV , DV = +5 V, AV , DV
AD775–SPECIFICATIONS CLOCK
= 20 MHz unless otherwise noted)
A
DD
Parameter
Min
RESOLUTION
8
DC ACCURACY
Integral Nonlinearity (INL)
Differential Nonlinearity (DNL)
No Missing Codes
Offset
To Top of Ladder VRT
To Bottom of Ladder VRB
DD
SS
AD775J
Typ
SS
= 0 V, VRT = 2.6 V, VRB = +0.6 V,
Max
Units
Bits
–10
0
+0.5
1.3
± 0.3
± 0.5
GUARANTEED
LSB
LSB
–35
+15
mV
mV
–60
+45
VIDEO ACCURACY1
Differential Gain Error
Differential Phase Error
1.0
0.5
%
Degrees
ANALOG INPUT
Input Range (VRT–VRB)
Input Capacitance
2.0
11
V p-p
pF
47
41
dB
dB
–51
–42
dB
dB
AC SPECIFICATIONS2
Signal-to-Noise and Distortion (S/(N + D))
fIN = 1 MHz
fIN = 5 MHz
Total Harmonic Distortion (THD)
fIN = 1 MHz
fIN = 5 MHz
REFERENCE INPUT
Reference Input Resistance (RREF)
Case 1: VRT = VRTS, VRB = VRBS
Reference Bottom Voltage (VRB)
Reference Span (VRT–VRB)
Reference Ladder Current (IREF)
Case 2: VRT = VRTS, VRB = AVSS
Reference Span (VRT–VRB)
Reference Ladder Current (IREF)
POWER SUPPLIES
Operating Voltages
AVDD
DVDD
Operating Current
IAVDD
IDVDD
IAVDD + IDVDD
230
300
450
Ω
0.60
1.96
4.4
0.64
2.09
7.0
0.68
2.21
9.6
V
V
mA
2.25
5
2.39
8
2.53
11
V
mA
+5.25
+5.25
Volts
Volts
9.5
2.5
12
17
mA
mA
mA
60
85
mW
+75
°C
+4.75
+4.75
POWER CONSUMPTION
TEMPERATURE RANGE
Operating
–20
NOTES
1
NSTC 40 IRE modulation ramp, CLOCK = 14.3 MSPS.
2
fIN amplitude = 0.3 dB full scale.
Specifications subject to change without notice. See Definition of Specifications for additional information.
–2–
REV. 0
(TA = +258C with AVDD, DVDD = +5 V, AVSS, DVSS = 0 V, VRT = 2.6 V, VRB = +0.6 V,
DIGITAL SPECIFICATIONS CLOCK = 20 MHz unless otherwise noted)
Parameter
LOGIC INPUT
High Level Input Voltage
Low Level Input Voltage
High Level Input Current
(VIH = DVDD)
Low Level Input Current
(VIL = 0 V)
Logic Input Capacitance
LOGIC OUTPUTS
High Level Output Current
OE = DVSS, VOH = DVDD–0.5 V
OE = DVDD, VOH = DVDD
Low Level Output Current
OE = DVSS, VOL = 0.4 V
OE = DVDD, VOL = 0 V
Symbol
DVDD
Min
VIH
VIL
5.0
5.0
4.0
IIH
5.25
IIL
CIN
5.25
IOH
IOZ
4.75
5.25
IOL
IOZ
4.75
5.25
AD775J
Typ
AD775
Max
Units
1.0
V
V
5
µA
µA
pF
–5
5
–1.1
16
mA
µA
16
mA
µA
3.7
TIMING SPECIFICATIONS
Symbol
Maximum Conversion Rate
Clock Period
Clock High
Clock Low
Output Delay
Pipeline Delay (Latency)
Sampling Delay
Aperture Jitter
tC
tCH
tCL
tOD
Min
Typ
20
50
25
25
35
Max
18
tDS
30
2.5
4
30
Specifications subject to change without notice.
SAMPLE N+1
SAMPLE N
SAMPLE N+2
VIN
tDS
tCH
tCL
CLK
tC
OUT
DATA N-3
tOD
DATA N-2
DATA N-1
Figure 1. AD775 Timing Diagram
REV. 0
–3–
DATA N
Units
MHz
ns
ns
ns
ns
Clock Cycles
ns
ps
AD775
PIN DESCRIPTION
Pin No.
Symbol
Type Name and Function
1
OE
DI
2, 24
3
4–9
10
11, 13
12
16
17
23
22
14, 15, 18
DVSS
D0 (LSB)
D1–D6
D7 (MSB)
DVDD
CLK
VRTS
VRT
VRB
VRBS
AVDD
P
DO
DO
DO
P
DI
AI
AI
AI
AI
P
19
20, 21
VIN
AVSS
AI
P
OE = Low
OE = High
Normal Operating Mode.
High Impedance Outputs.
Digital Ground. Note: DVSS and AVSS pins should share a common ground plane on the circuit board.
Least Significant Bit, Data Bit 0.
Data Bits 1 Through 6.
Most Significant Bit, Data Bit 7.
+5 V Digital Supply. Note: DVDD and AVDD pins should share a common supply on the circuit board.
Clock Input.
Reference Top Bias. Short to VRT for Self-Bias.
Reference Ladder Top.
Reference Ladder Bottom.
Reference Bottom Bias. Short to VRB for Self-Bias.
+5 V Analog Supply. Note: DVDD and AVDD pins should share a common supply within 0.5 inches
of the AD775.
Analog Input. Input Span = VRT–VRB.
Analog Ground. Note: DVSS and AVSS pins should share a common ground within 0.5 inches of the
AD775.
NOTE
Type: AI = Analog Input; DI = Digital Input; DO = Digital Output; P = Power.
PIN CONFIGURATION
(DIP and SOIC)
MAXIMUM RATINGS*
Supply Voltage (AVDD, DVDD) . . . . . . . . . . . . . . . . . . . . 7 V
Supply Difference (AVDD–DVDD) . . . . . . . . . . . . . . . . . . 0 V
Ground Difference (AVSS–DVSS) . . . . . . . . . . . . . . . . . . . 0 V
Reference Voltage (VRT, VRB) . . . . . . . . . . . . . . . . VDD to VSS
Analog Input Voltage (VIN) . . . . . . . . . . . . . . . . . . VDD to VSS
Digital Input Voltage (CLK) . . . . . . . . . . . . . . . . . VDD to VSS
Digital Output Voltage (VOH, VOL) . . . . . . . . . . . . VDD to VSS
Storage Temperature . . . . . . . . . . . . . . . . . . –55°C to +150°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 sections of this specification is not implied. Exposure to absolute
maximum rating conditions for extended periods may affect device reliability.
ORDERING GUIDE
Model
Temperature
Range
Package
Description
Package
Option
AD775JN –20°C to +75°C 24-Pin 400 Mil Plastic DIP N-24B
AD775JR –20°C to +75°C 24-Pin 300 Mil SOIC
R-24A
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 AD775 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.
–4–
WARNING!
ESD SENSITIVE DEVICE
REV. 0
AD775
–30
54
48
42
–36
THD – dB
S/(N + D) – dB
36
30
24
–42
18
–48
12
6
0
0.1
1
–54
0.1
10
1
Figure 5. THD vs. Input Frequency at 20 MSPS Clock Rate
(VIN = –0.3 dB)
0
0
–10
–10
–20
–20
–30
–30
–40
–40
–50
dB
dB
Figure 2. S/(N + D) vs. Input Frequency at 20 MSPS Clock
Rate (VIN = –0.3 dB)
–50
–60
–60
–70
–70
–80
–80
–90
–90
–100
–100
0
1.0
2.0
3.0
4.0
5.0
10
fIN – MHz
fIN – MHz
6.0
7.0
8.0
9.0
10.0
0
FREQUENCY – MHz
1.0
2.0
3.0
4.0
5.0
6.0
7.0
8.0
9.0
10.0
FREQUENCY – MHz
Figure 3. Typical FFT at 1 MHz Input, 20 MSPS Clock Rate
(VIN = –0.5 dB)
Figure 6. Typical FFT at 5 MHz Input, 20 MSPS Clock Rate
(VIN = –0.5 dB)
+0.4
+1
+0.3
+0.1
INL – LSB
DNL – LSB
+0.2
0
–0.1
0
–0.2
–0.3
–0.4
–FULLSCALE
–1
–FULLSCALE
+FULLSCALE
Figure 4. Typical Differential Nonlinearity (DNL)
REV. 0
+FULLSCALE
Figure 7. Typical Integral Nonlinearity (INL)
–5–
AD775
DEFINITIONS OF SPECIFICATIONS
Integral Nonlinearity (INL)
Differential Phase
Integral nonlinearity refers to the deviation of each individual
code from a line drawn from “zero” through “full scale.” The
point used as “zero” occurs 1/2 LSB before the first code transition. “Full scale” is defined as a level 1 1/2 LSB beyond the
last code transition. The deviation is measured from the center
of each particular code to the true straight line.
Pipeline Delay (Latency)
Differential Nonlinearity (DNL, No Missing Codes)
An ideal ADC exhibits code transitions that are exactly 1 LSB
apart. DNL is the deviation from this ideal value. It is often
specified in terms of the resolution for which no missing codes
(NMC) is guaranteed.
Offset Error
The first code transition should occur at a level 1/2 LSB above
nominal negative full scale. Offset referred to the Bottom of
Ladder VRB is defined as the deviation from this ideal. The last
code transition should occur 1 1/2 LSB below the nominal
positive full scale. Offset referred to the Top of Ladder VRT is
defined as the deviation from this ideal.
The difference in the output phase of a small high frequency
sine wave at two stated levels of a low frequency signal on which
it is superimposed.
The number of clock cycles between conversion initiation and
the associated output data being made available. New output
data is provided every clock cycle.
Signal-to-Noise Plus Distortion Ratio (S/N+D)
S/N+D is the ratio of the rms value of the measured input signal
to the rms sum of all other spectral components including harmonics but excluding dc. The value for S/N+D is expressed in
decibels.
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 as a percentage or in decibels.
Differential Gain
The percentage difference between the output amplitudes of a
small high frequency sine wave at two stated levels of a low frequency signal on which it is superimposed.
THEORY OF OPERATION
APPLYING THE AD775
The AD775 uses a pipelined two-step (subranging) flash architecture to achieve significantly lower power and lower input
capacitance than conventional full flash converters while still
maintaining high throughput. The analog input is sampled by
the switched capacitor comparators on the falling edge of the
input clock: no external sample and hold is required. The coarse
comparators determine the top four bits (MSBs), and select the
appropriate reference ladder taps for the fine comparators. With
the next falling edge of the clock, the fine comparators determine
the bottom four bits (LSBs). Since the LSB comparators require
a full clock cycle between their sampling instant and their decision, the converter alternates between two sets of fine comparators in a “ping-pong” fashion. This multiplexing allows a new
input sample to be taken on every falling clock edge, thereby
providing 20 MSPS operation. The data is accumulated in the
correction logic and output through a three-state output latch
on the rising edge of the clock. The latency between input sampling and the corresponding converted output is 2.5 clock cycles.
REFERENCE INPUT
The AD775 features a resistive reference ladder similar to that
found in most conventional flash converters. The analog input
range of the converter falls between the top (VRT) and bottom
(VRB) voltages of this ladder. The nominal resistance of the ladder is 300 ohms, though this may vary from 230 ohms to 450
ohms. The minimum recommended voltage for VRB is 0 V; the
linearity performance of the converter may deteriorate for input
spans (VRB–VRB) below 1.8 V. While 2.8 V is the recommended
maximum ladder top voltage (VRT), the top of the ladder may be
as high as the positive supply voltage (AVDD) with minimal linearity degradation.
AVDD
325Ω
AD775
16
17
All three comparator banks utilize the same resistive ladder for
their reference input. The analog input range is determined by
the voltages applied to the bottom and top of the ladder, and
the AD775 can digitize inputs down to 0 V using a single supply. On-chip application resistors are provided to allow the
ladder to be conveniently biased by the supply voltage.
0.1µF
300Ω
*VALUES FOR
RESISTANCE
ARE TYPICAL
23
22
The AD775 uses switched capacitor autozeroing techniques to
cancel the comparators’ offsets and achieve excellent differential
nonlinearity performance: typically ± 0.3 LSB. The integral
nonlinearity is determined by the linearity of the reference ladder and is typically +0.5 LSB.
0.1µF
90Ω
AV SS
Figure 8. Reference Configuration: 0.64 V to 2.73 V
To simplify biasing of the AD775, on-chip reference bias resistors are provided on Pins 16 and 22. The two recommended
configurations for these resistors are shown in Figures 8 and 9.
–6–
REV. 0
AD775
In the topology shown in Figure 8, the top of the ladder (VRT)
is shorted to the top bias resistor (VRTS) (Pin 17 shorted to Pin
16), while the bottom of the ladder (VRB) is shorted to the bottom bias resistor (VRBS) (Pin 23 shorted to Pin 22). This creates
a resistive path (nominally 725 ohms) between AVDD and AVSS.
For nominal supply voltages (5 V and 0 V respectively), this
creates an input range of 0.64 V to 2.73 V.
NC
10kΩ
+5V
0.1µF
AD680
3 VIN
VOUT
GND
500pF
AD775
2
2
422Ω
20Ω
AD822
1
0.1µF
1
3
23 VRB
500pF
422Ω
The topology shown in Figure 9 provides a ground-inclusive
input range. The bottom of the ladder (VRB) is shorted to AVSS.
(0 V), while the top of the ladder (VRT) is connected to the onboard bias resistor (VRTS). This provides a nominal input range
of 0 V to +2.4 V for AVDD of 5 V. The VRBS pin may be left
floating, or shorted to AVSS.
NC = NO CONNECT
AD822
Figure 11. Reference Configuration: 0.7 V to 3.2 V
ANALOG INPUT
The impedance looking into the analog input is essentially
capacitive, as shown in the equivalent circuit of Figure 12, typically totalling around 11 pF. A portion of this capacitance is
parasitic; the remainder is part of the switched capacitor structure of the comparator arrays. The switches close on the rising
edge of the clock, acquire the input voltage, and open on the
clock’s falling edge (the sampling instant). The charge that must
be moved onto the capacitors during acquisition will be a function of the converter’s previous two samples, but there should be
no sample-to-sample crosstalk so long as ample driving impedance and acquisition time are provided.
AD775
16
17
300Ω
*VALUES FOR
RESISTANCE
ARE TYPICAL
90Ω
AVSS
Figure 9. Reference Configuration: 0 V to +2.4 V
SWITCHES EACH
CLOCK CYCLE
AVDD
More elaborate topologies can be used for those wishing to
provide an input span based on an external reference voltage.
The circuit in Figure 10 uses the AD780 2.5 V reference to
drive the top of the ladder (VRT), with the bottom (VRB) of the
ladder grounded to provide an input span of 0 V to +2.5 V. This is
modified in Figure 11 to shift the 2.5 V span up 700 mV.
C2
VIN
C1
+5V
NC
1
AD780
C1 + C2 + C3 ≈ 11pF
8
NC
2
7
NC
NC
3
6
4
5
NC
0.1µF
0.1µF
AD775
16
Figure 12. Equivalent Analog Input Circuit (VIN)
17
NC
SWITCHES ON ALTERNATE
CLOCK CYCLES
C3
AVSS
NC
7
140Ω
AVDD
For example, to ensure accurate acquisition (to 1/4 bit accuracy)
of a full-scale input step in less than 20 ns, a source impedance
of less than 100 ohms is recommended. Figure 13 shows one
option of input buffer circuitry using the AD817. The AD817
acts as both an inverting buffer and level shifting circuit. In
order to level shift the ground-based input signal to the dc level
required by the input of the AD775, the supply voltage is resistively divided to produce the appropriate voltage at the noninverting input of the AD817. For most applications, the AD817
provides a low cost, high performance level shifter. The AD811
is recommended for systems which require faster settling times.
AD775
22
23
NC = NO CONNECT
Figure 10. Reference Configuration: 0 V to 2.5 V
The AD775 can accommodate dynamic changes in the reference
voltage for gain or offset adjustment. However, conversions that
are in progress, including those in the converter pipeline, while
the reference voltages are changing will be invalid.
REV. 0
20Ω
5
325Ω
22
0.1µF
10kΩ
6
AV SS
22 VRBS
NC
10kΩ
Both top and bottom of the reference ladder should be decoupled, preferably with a chip capacitor to ground to minimize
reference noise.
23
VRTS
17 VRT
0.1µF
0.1µF
16
10kΩ
–7–
AD775
1kΩ
100
1kΩ
AD775
0V DC
90
1.5VDC
AD817
5.6kΩ
POWER DISSIPATION – mW
19 AIN
+5V
10µF
1kΩ
Figure 13. Level Shifting Input Buffer
The analog input range is set by the voltage at the top and bottom of the reference ladder. In general, the larger the span
(VRT–VRB), the better the differential nonlinearity (DNL) of the
converter; a 1.8 V span is suggested as a minimum to realize
good linearity performance. AS the input voltage exceeds 2.8 V
(for AVDD = 4.75 V), the input circuitry may start to slightly
degrade the acquisition performance.
CLOCK INPUT
The AD775’s internal control circuitry makes use of both clock
edges to generate on-chip timing signals. To ensure proper
settling and linearity performance, both tCH and tCL times
should be 25 ns or greater. For sampling frequencies at or near
20 MSPS, a 50% duty cycle clock is recommended. For slower
sampling applications, the AD775 can accommodate a wider
range of duty cycles, provided each clock phase is as least 25 ns.
Under certain conditions, the AD775 can be operated at sampling rates above 20 MSPS. Figure 14 shows the signal-to-noise
plus distortion (S/(N+D)) performance of a typical AD775
versus clock frequency. It is extremely important to note that the
maximum clock rate will be a strong function of both temperature and
supply voltage. In general, the part slows down with increasing
temperature and decreasing supply voltage.
50
S(N + D) – dB
40
80
70
60
50
40
30
0
10
30
20
CLOCK FREQUENCY – MHz
40
Figure 15. Power Dissipation vs. Clock Frequency
In applications sensitive to aperture jitter, the clock signal
should have a fall time of less than 3 ns. High speed CMOS
logic families (HC/HCT) are recommended for their symmetrical swing and fast rise/fall times. Care should be taken to minimize the fanout and capacitive loading of the clock input line.
DIGITAL INPUTS AND OUTPUTS
The AD775’s digital interface uses standard CMOS, with logic
thresholds roughly midway between the supplies (DVSS, DVDD).
The digital output is presented in straight binary format, with
full scale (1111 1111) corresponding to VIN = VRT, and zero
(0000 0000) corresponding to VIN = VRB. Excessive capacitive
loading of the digital output lines will increase the dynamic
power dissipation as well as the on-chip digital noise. Logic
fanout and parasitic capacitance on these lines should be minimized for optimum noise performance.
The data output lines may be placed in a high output impedance
state by bringing OE (Pin 1) to a logic high. Figure 16 indicates
typical timing for access and float delay times (tHL and tDD
respectively). Note that even when the outputs are in a high
impedance state, activity on the digital bus can couple back to
the sensitive analog portions of the AD775 and corrupt conversions in progress.
30
OE
20
tDD
DATA
OUTPUT
10
0
0.1
DATA ACTIVE
THREE-STATE
(HIGH IMPEDANCE)
tDD = 18ns TYPICAL
1
10
tHL
tHL = 12ns TYPICAL
100
CLOCK FREQUENCY – MHz
Figure 16. High Impedance Output Timing
Figure 14. S(N + D) vs. Clock Frequency (Temperature
= +25°C)
A significant portion of the AD775’s power dissipation is proportional to the clock frequency: Figure 15 illustrates this
tradeoff for a typical part.
–8–
REV. 0
AD775
POWER SUPPLY CONNECTIONS AND DECOUPLING
APPLICATIONS
The analog and digital supplies of the AD775 have been separate to prevent the typically large transients associated with the
on-chip digital circuitry from coupling into the analog supplies
(AVDD, AVSS). However, in order to avoid possible latch-up
conditions, AVDD and DVDD must share a common supply
external to the part, preferably a common source somewhere on
the PC board.
AD775 EVALUATION BOARD
Figures 17 through 22 show the schematic and printed circuit
board (PCB) layout for the AD775 evaluation board. Referring
to Figure 17, the input signal is buffered by U3, an AD817 op
amp configured as a unity-gain follower. The signal is then accoupled and dc-biased by adjusting potentiometer R14. Video
and imaging applications would typically use a dc-restoration
circuit instead of the manual potentiometer adjustment. Q1, an
emitter-follower, buffers the input signal and provides ample
current to drive a simple low-pass filter. The filtering is included
to limit wideband noise and highlight the fact that the AD775
can be driven from a nonzero source impedance.
Each supply should be decoupled by a 0.1 µF capacitor located
as close to the device pin as possible. Surface-mount capacitors,
by virtue of their low parasitic inductance, are preferable to
through-hole types. A larger capacitor (10 µF electrolytic)
should be located somewhere on the board to help decouple
large, low frequency supply noise. For specific layout information, refer to the AD775 Evaluation Board section of the data
sheet.
J8
CLOCK
(
) TP10
+5VA
+5VA
R15
499
5
CR1
1N4148
R14
500
VCC
R13
20
C5
1/6
U7
R11
75
C7
10pF
VCC
+5VA
C15
A
3
R9
10k
C13
A
VIN VOUT
2
1/2 U2
2
AD822
3
1
A
J6
C14
8
C9
A
J4
J5
J2
R7
10k
R1
500
AD822
5
16 VRTS
D6
U5
D5
D4
7
D3
6
22 VRBS
D0
3
4
5
6
7
5
8
4
9
3
DV SS
2
OE
1
1
2
8
19 VIN
D1
D
9
18 AVDD
D2
J10
10
G1
VCC
A1
G2
A2
Y1
A3
U6
Y2
A4
Y3
A5
Y4
A6
Y5
A7
Y6
A8
Y7
GND
Y8
C22
19
D
18
17
16
15
14
13
12
11
J9
D
D
D
7
4
TP12
A
A
J7
+5V
NOTES
78M05
VCC
1
3
5
2
4
U4
TP7 VCC
6 TP11 VEE
C21
TP6
+5VA
D
GND
C16
C19
= 47µF ELECTROLYTIC CAPACITOR
UNLESS OTHERWISE NOTED
= 0.1µF CERAMIC CAPACITOR
UNLESS OTHERWISE NOTED
VIN VOUT
TP8
C11
A
C20
VEE
Figure 17. AD775 Evaluation Board Schematic
REV. 0
D
20
R5
20
1/2 U2
6
A
D7 10
24 DVSS
TP3
VRB
C3
390pF
R6
10k
R2
500
15 AVDD
23 VRB
A
+5VA
C1
A
DV DD 11
21 AVSS
C12
74ALS541
CLK 12
14 AVDD
20 AVSS
1
A
R3
499
R10
20
D
AD775
17 VRT
C4
390pF
GND
C2
J3
A
1
+5V
TP4
VRT
AD680
P2-40 PIN IDC
C18
VEE
13 DVDD
U1
TP13
ENABLE
+5V
D
+5VA
1/6
U7
D
Q1
2N3904
R12
4.99k
R8
10k
8
TP5
VIN
A
A
9
C8
22µF
C6
VEE
6
R16
49.9
TP9
A
U3
J1
2
ANALOG TP2
INPUT
6
AD817
7
3
4
R4
TP1
49.9
The reference circuit is similar to the one shown in Figure 11
with the exception that R1 and R2 allow precise adjustment of
–9–
40
D
AD775
VRT and VRB. Note that the VRT and VRB traces (see Figures 19
and 20) are run in parallel and in the same proximity. Any noise
coupling is likely to be common mode to both signals and would
result in an offset error but not a gain error. The entire reference
circuit is powered by a single +5 V supply. The minimum voltage for VRB is determined by the impedance of the AD822 output stage and the amount of current flowing through the
internal resistor ladder of the AD775.
portant aspect is the power and ground distribution. While the
AD775 has separate analog and digital power and ground pins,
the AD775 should be treated as an entirely analog component.
The ground plane is joined close to the ADC in order to maintain a low potential difference across the analog and digital
ground pins. Because the power and grounds are derived from a
common point, a slit in the ground plane is used to minimize
any interaction between the analog and digital return currents.
The sampling clock is buffered by U7, a 74HC04 inverter. It is
recommended that the output loading of the inverter is minimized in order to maintain fast transition times on the clock. An
additional inverter is used to provide a buffered clock signal
whose rising edges indicate that data is valid. A 74ALS541
buffers the eight digital data outputs of the AD775 to improve
the load driving capability.
The power for the AD775, AVDD and DVDD, are derived from
the same supply. Separate traces are run to AVDD and DVDD
and joined together at the source. While not used on the evaluation board, a ferrite bead or inductor can effectively isolate noise
generated by digital circuitry such as the output buffers. In cases
where only a single supply is available, the inductor should not
be placed between AVDD and DVDD. Instead, both supplies of
the AD775 should be connected together and isolated from
entirely digital components.
The multilayer PCB board layout shows some of the important
design guidelines recommended for the AD775. The most im-
Table I. Components List
Reference Designator
Description
Quantity
R1, R2, R14
R3, R15
R4, R13, R16
R5, R10
R6–R9
R11
R12
CR1
C1, C2, C5, C6, C9, C12–C15, C18
C20, C22, C23
C3, C4
C7
C8
C11, C16, C19, C21
Q1
U1
U2
U3
U4
U5
U6
U7
J1, J8
Potentiometer
Resistor, 1%, 499 Ω
Resistor, 1%, 49.9 Ω
Resistor, 1%, 20 Ω
Resistor, 1%, 10 kΩ
Resistor, 1%, 75 Ω
Resistor, 1%, 4.99 kΩ
Diode, 1N4148
3
2
3
2
4
1
1
1
Ceramic Cap, Z5U, 0.1 µF
Capacitor, Mica, 390 pF
Capacitor, Mica, 10 pF
Capacitor, Tantalum, 22 µF, 16 V
Capacitor, Alum. Electrolytic, 47 µF, 16 V
Transistor, 2N3904
AD680JT
AD822AN
AD817AN
78M05
AD775
74ALS541N
74HC04N
BNC Jack
13
2
1
1
4
1
1
1
1
1
1
1
1
2
–10–
REV. 0
AD775
Figure 18. Silkscreen Layer (Not to Scale)
Figure 20. Solder Side PCB Layout (Not to Scale)
Figure 19. Component Side PCB Layout (Not to Scale)
Figure 21. Ground Plane PCB Layout (Not to Scale)
REV. 0
–11–
C1830–18–8/93
AD775
Figure 22. Power Plane PCB Layout (Not to Scale)
OUTLINE DIMENSIONS
Dimensions shown in inches and (mm).
Plastic DIP (N-24B)
24
SOIC (R-24A)
13
24
12
1
1.205 (30.60)
1.185 (30.10)
0.200 (5.05)
0.125 (3.18)
0.100
(2.54)
BSC
0.053 (1.35)
0.041 (1.05)
0.221 (5.6)
0.205 (5.2)
12
1
0.020
(0.50)
MIN
0.118 (3.00)
MIN
0.024 (0.60)
0.016 (0.40)
13
PIN 1
SEATING
PLANE
0.327 (8.3)
0.295 (7.5)
0.400 (10.16)
0.195 (4.95)
0.125 (3.18)
15°
0°
0.014 (0.35)
0.008 (0.20)
0.012 (0.12)
0.002 (0.05)
–12–
0.089 (2.25)
0.067 (1.70)
0.606 (15.4)
0.586 (14.9)
0.050 (1.27)
BSC
0.272 (6.9)
0.022 (0.55)
0.014 (0.35)
0.012 (0.30)
0.006 (0.15)
0.028 (0.7)
0.012 (0.3)
REV. 0
PRINTED IN U.S.A.
0.346 (8.80)
0.330 (8.40)
PIN 1