AD AD9260

The AD9260 is a switched-capacitor ADC with a nominal fullscale input range of 4 V. It offers a differential input with 60 dB
of common-mode rejection of common-mode signals. The signal range of each differential input is ± 1 V centered on a 2.0 V
common-mode level.
The on-chip decimation filter is configured for maximum performance and flexibility. A series of three half-band FIR filter
stages provide 8× decimation filtering with 85 dB of stopband
attenuation and 0.004 dB of passband ripple. An onboard digital multiplexer allows the user to access data from the various
stages of the decimation filter.
The on-chip programmable reference and reference buffer amplifier are configured for maximum accuracy and flexibility. An
external reference can also be chosen to suit the user’s specific
dc accuracy and drift requirements.
16-BIT: 10MHz
STAGE 1:2X
DECIMATION
FILTER
16-BIT: 5MHz
STAGE 2:2X
DECIMATION
FILTER
REF
BOTTOM
16-BIT: 2.5MHz
STAGE 3:2X
DECIMATION
FILTER
REFERENCE
BUFFER
COMMON
MODE
DRVSS
OTR
OUTPUT REGISTER
DIGITAL
DEMODULATOR
12-BIT: 20MHz
REF TOP
DRVDD
AVSS
AVSS
AVDD
DVDD
AD9260
VREF
REFCOM
The AD9260 is a 16-bit, high-speed oversampled analog-todigital converter (ADC) that offers exceptional dynamic range
over a wide bandwidth. The AD9260 is manufactured on an
advanced CMOS process. High dynamic range is achieved with
an oversampling ratio of 8× through the use of a proprietary
technique that combines the advantages of sigma-delta and
pipeline converter technologies.
DVSS
MULTIBIT
SIGMA-DELTA
MODULATOR
VINB
SENSE
PRODUCT DESCRIPTION
RESET/
SYNC
OUTPUT MODE MULTIPLEXER
VINA
AVSS
FUNCTIONAL BLOCK DIAGRAM
AVDD
FEATURES
Monolithic 16-Bit, Oversampled A/D Converter
8 Oversampling Mode, 20 MSPS Clock
2.5 MHz Output Word Rate
1.01 MHz Signal Passband w/0.004 dB Ripple
Signal-to-Noise Ratio: 88.5 dB
Total Harmonic Distortion: –96 dB
Spurious Free Dynamic Range: 100 dB
Input Referred Noise: 0.6 LSB
Selectable Oversampling Ratio: 1, 2, 4, 8
Selectable Power Dissipation: 150 mW to 585 mW
85 dB Stopband Attenuation
0.004 dB Passband Ripple
Linear Phase
Single +5 V Analog Supply, +5 V/+3 V Digital Supply
Synchronize Capability for Parallel ADC Interface
Twos-Complement Output Data
44-Lead MQFP
AVDD
a
High-Speed Oversampling CMOS
ADC with 16-Bit Resolution
at a 2.5 MHz Output Word Rate
AD9260
BIT1–BIT16
DAV
BANDGAP
REFERENCE
BIAS
CIRCUIT
CLOCK
BUFFER
MODE
REGISTER
BIAS ADJUST
CLK
MODE
READ
CS
The AD9260 operates on a single +5 V supply, typically consuming 585 mW of power. A power scaling circuit is provided
allowing the AD9260 to operate at power consumption levels as
low as 150 mW at reduced clock and data rates. The AD9260 is
available in a 44-lead MQFP package and is specified to operate
over the industrial temperature range.
PRODUCT HIGHLIGHTS
The AD9260 is fabricated on a very cost effective CMOS
process. High-speed, precision mixed-signal analog circuits are
combined with high-density digital filter circuits.
The AD9260 offers a complete single-chip 16-bit sampling
ADC with a 2.5 MHz output data rate in a 44-lead MQFP.
Selectable Internal Decimation Filtering—The AD9260
provides a high-performance decimation filter with 0.004 dB
passband ripple and 85 dB of stopband attenuation. The filter
is configurable with options for 1×, 2×, 4×, and 8× decimation.
Power Scaling—The AD9260 consumes a low 585 mW of power
at 16-bit resolution and 2.5 MHz output data rate. Its power
can be scaled down to as low as 150 mW at reduced clock rates.
Single Supply— Both of the analog and digital portions of the
AD9260 can operate off of a single +5 V supply simplifying
system power supply design. The digital logic will also accommodate a single +3 V supply for reduced power.
REV. B
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: 781/329-4700
World Wide Web Site: http://www.analog.com
Fax: 781/326-8703
© Analog Devices, Inc., 2000
AD9260–SPECIFICATIONS
CLOCK INPUT FREQUENCY RANGE
Parameter—Decimation Factor (N)
AD9260 (8)
AD9260 (4)
AD9260 (2)
AD9260 (1)
Units
CLOCK INPUT (Modulator Sample Rate, fCLOCK)
1
20
1
20
1
20
1
20
kHz min
MHz max
OUTPUT WORD RATE (FS = fCLOCK/N)
0.125
2.5
0.250
5
0.500
10
1
20
kHz min
MHz max
Specifications subject to change without notice
(AVDD = +5 V, DVDD = +3 V, DRVDD = +3 V, fCLOCK = 20 MSPS, VREF = +2.5 V, Input CML = 2.0 V TMIN to TMAX
BIAS = 2 k)
DC SPECIFICATIONS unless otherwise noted, R
Parameter—Decimation Factor (N)
AD9260 (8)
AD9260 (4)
AD9260 (2)
AD9260 (1)
Units
RESOLUTION
16
16
16
12
Bits min
INPUT REFERRED NOISE (TYP)
1.0 V Reference
2.5 V Reference1
1.40
0.68 (90.6)
2.4
1.2 (86)
6.0
3.7 (76)
1.3
1.0 (63.2)
LSB rms typ
LSB rms typ (dB typ)
ACCURACY
Integral Nonlinearity (INL)
Differential Nonlinearity (DNL)
No Missing Codes
Offset Error
Gain Error2
Gain Error3
± 0.75
± 0.50
16
0.9 (0.5)
2.75 (0.66)
1.35 (0.7)
± 0.75
± 0.50
16
(0.5)
(0.66)
(0.7)
± 0.75
± 0.50
16
(0.5)
(0.66)
(0.7)
± 0.3
± 0.25
12
(0.5)
(0.66)
(0.7)
LSB typ
LSB typ
Bits Guaranteed
% FSR max (typ @ +25°C)
% FSR max (typ @ +25°C)
% FSR max (typ @ +25°C)
TEMPERATURE DRIFT
Offset Error
Gain Error2
Gain Error3
2.5
22
7.0
2.5
22
7.0
2.5
22
7.0
2.5
22
7.0
ppm/°C typ
ppm/°C typ
ppm/°C typ
POWER SUPPLY REJECTION
AVDD, DVDD, DRVDD (+5 V ± 0.25 V)
0.06
0.06
0.06
0.06
% FSR max
1.6
4.0
+0.5
+AVDD – 0.5
10.2
1.6
4.0
+0.5
+AVDD – 0.5
10.2
1.6
4.0
+0.5
+AVDD – 0.5
10.2
1.6
4.0
+0.5
+AVDD – 0.5
10.2
V p-p Diff. max
V p-p Diff. max
V min
V max
pF typ
1
± 14
2.5
± 35
1
± 14
2.5
± 35
1
± 14
2.5
± 35
1
± 14
2.5
± 35
V typ
mV max
V typ
mV max
0.5
2.0
0.5
2.0
0.5
2.0
0.5
2.0
mV max
mV max
8
8
8
8
kΩ
ANALOG INPUT
Input Span
VREF = 1.0 V
VREF = 2.5 V
Input (VINA or VINB) Range
Input Capacitance
INTERNAL VOLTAGE REFERENCE
Output Voltage (1 V Mode)
Output Voltage Error (1 V Mode)
Output Voltage (2.5 V Mode)
Output Voltage Error (2.5 V Mode)
Load Regulation4
1 V REF
2.5 V REF
REFERENCE INPUT RESISTANCE
–2–
REV. B
AD9260
Parameter—Decimation Factor (N)
AD9260 (8)
AD9260 (4)
AD9260 (2)
AD9260 (1)
Units
+5
+5.5
+2.7
+5
+5.5
+2.7
+5
+5.5
+2.7
+5
+5.5
+2.7
V (± 5%)
V max
V min
115
115
115
IDVDD
12.5
10.3
6.5
IDRVDD
0.450
0.850
1.7
115
134
2.4
3.5
2.6
mA typ
mA max
mA typ
mA max
mA typ
613
608
600
585
630
mW typ
mW max
POWER SUPPLIES
Supply Voltages
AVDD
DVDD and DRVDD
Supply Current
IAVDD
POWER CONSUMPTION
NOTES
1
VINA and VINB Connect to DUT CML.
2
Including Internal 2.5 V reference.
3
Excluding Internal 2.5 V reference.
4
Load regulation with 1 mA load Current (in addition to that required by AD9260).
Specifications subject to change without notice.
(AVDD = +5 V, DVDD = +3 V, DRVDD = +3 V, fCLOCK = 20 MSPS, VREF = +2.5 V, Input CML = 2.0 V TMIN to TMAX
BIAS = 2 k)
AC SPECIFICATIONS unless otherwise noted, R
Parameter—Decimation Factor (N)
DYNAMIC PERFORMANCE
INPUT TEST FREQUENCY: 100 kHz (typ)
Signal-to-Noise Ratio (SNR)
Input Amplitude = –0.5 dBFS
Input Amplitude = –6.0 dBFS
SNR and Distortion (SINAD)
Input Amplitude = –0.5 dBFS
Input Amplitude = –6.0 dBFS
Total Harmonic Distortion (THD)
Input Amplitude = –0.5 dBFS
Input Amplitude = –6.0 dBFS
Spurious Free Dynamic Range (SFDR)
Input Amplitude = –0.5 dBFS
Input Amplitude = –6.0 dBFS
INPUT TEST FREQUENCY: 500 kHz
Signal-to-Noise Ratio (SNR)
Input Amplitude = –0.5 dBFS
Input Amplitude = –6.0 dBFS
SNR and Distortion (SINAD)
Input Amplitude = –0.5 dBFS
Input Amplitude = –6.0 dBFS
Total Harmonic Distortion (THD)
Input Amplitude = –0.5 dBFS
Input Amplitude = –6.0 dBFS
Spurious Free Dynamic Range (SFDR)
Input Amplitude = –0.5 dBFS
Input Amplitude = –6.0 dBFS
REV. B
AD9260(8)
AD9260(4)
AD9260(2)
AD9260(1)
Units
88.5
82.5
82
78
74
68
63
58
dB typ
dB typ
87.5
82
82
77.5
74
69
63
58
dB typ
dB typ
–96
–93
–96
–98
–97
–96
–98
–98
dB typ
dB typ
100
94
98
100
98
94
88
84
dB typ
dB typ
86.5
80.5
82.5
82
74
63
77
68
58
dB typ
dB min
dB typ
86.0
80.0
82.0
81
74
63
77
68
58
–97.0
–90.0
–95.5
–92
–89
–86
–96
–89
–86
99.0
90.0
98
92
91
88
100
91
82
–3–
dB typ
dB min
dB typ
dB typ
dB max
dB typ
dB typ
dB max
dB typ
AD9260–SPECIFICATIONS
AC SPECIFICATIONS (Continued)
Parameter—Decimation Factor (N)
DYNAMIC PERFORMANCE (Continued)
INPUT TEST FREQUENCY: 1.0 MHz (typ)
Signal-to-Noise Ratio (SNR)
Input Amplitude = –0.5 dBFS
Input Amplitude = –6.0 dBFS
SNR and Distortion (SINAD)
Input Amplitude = –0.5 dBFS
Input Amplitude = –6.0 dBFS
Total Harmonic Distortion (THD)
Input Amplitude = –0.5 dBFS
Input Amplitude = –6.0 dBFS
Spurious Free Dynamic Range (SFDR)
Input Amplitude = –0.5 dBFS
Input Amplitude = –6.0 dBFS
INPUT TEST FREQUENCY: 2.0 MHz (typ)
Signal-to-Noise Ratio (SNR)
Input Amplitude = –0.5 dBFS
Input Amplitude = –6.0 dBFS
SNR and Distortion (SINAD)
Input Amplitude = –0.5 dBFS
Input Amplitude = –6.0 dBFS
Total Harmonic Distortion (THD)
Input Amplitude = –0.5 dBFS
Input Amplitude = –6.0 dBFS
Spurious Free Dynamic Range (SFDR)
Input Amplitude = –0.5 dBFS
Input Amplitude = –6.0 dBFS
INPUT TEST FREQUENCY: 5.0 MHz (typ)
Signal-to-Noise Ratio (SNR)
Input Amplitude = –0.5 dBFS
Input Amplitude = –6.0 dBFS
SNR and Distortion (SINAD)
Input Amplitude = –0.5 dBFS
Input Amplitude = –6.0 dBFS
Total Harmonic Distortion (THD)
Input Amplitude = –0.5 dBFS
Input Amplitude = –6.0 dBFS
Spurious Free Dynamic Range (SFDR)
Input Amplitude = –0.5 dBFS
Input Amplitude = –6.0 dBFS
AD9260 (8)
AD9260 (4)
AD9260 (2)
AD9260 (1)
Units
85
80
82
76
74
68
63
58
dB typ
dB typ
84.5
80
81
76
74
69
63
58
dB typ
dB typ
–102
–96
–96
–94
–82
–84
–79
–77
dB typ
dB typ
105
98
98
96
83
87
80
80
dB typ
dB typ
82
76
74
68
63
58
dB typ
dB typ
81
76
73
69
62
58
dB typ
dB typ
–101
–95
–80
–80
–75
–76
dB typ
dB typ
104
100
80
83
78
79
dB typ
dB typ
59
57
dB typ
dB typ
58
57
dB typ
dB typ
–58
–67
dB typ
dB typ
59
70
dB typ
dB typ
INTERMODULATION DISTORTION
fIN1 = 475 kHz, fIN2 = 525 kHz
fIN1 = 950 kHz, fIN2 = 1.050 MHz
–93
–95
–91
–86
–91
–85
–83
–83
dBFS typ
dBFS typ
DYNAMIC CHARACTERISTICS
Full Power Bandwidth
Small Signal Bandwidth (A IN = –20 dBFS)
Aperture Jitter
75
75
2
75
75
2
75
75
2
75
75
2
MHz typ
MHz typ
ps rms typ
Specifications subject to change without notice.
–4–
REV. B
AD9260
DIGITAL FILTER CHARACTERISTICS
Parameter
8× DECIMATION (N = 8)
Passband Ripple
Stopband Attenuation
Passband
Stopband
Passband/Transition Band Frequency
(–0.1 dB Point)
(–3.0 dB Point)
Absolute Group Delay1
Group Delay Variation
Settling Time (to ± 0.0007%)1
4× DECIMATION (N = 4)
Passband Ripple
Stopband Attenuation
Passband
Stopband
Passband/Transition Band Frequency
(–0.1 dB Point)
(–3.0 dB Point)
Absolute Group Delay1
Group Delay Variation
Settling Time (to ± 0.0007%)1
2× DECIMATION (N = 2)
Passband Ripple
Stopband Attenuation
Passband
Stopband
Passband/Transition Band Frequency
(–0.1 dB Point)
(–3.0 dB Point)
Absolute Group Delay1
Group Delay Variation
Settling Time (to ± 0.0007%)1
1× DECIMATION (N = 1)
Propagation Delay: tPROP
Absolute Group Delay
AD9260
Units
0.00125
82.5
0
0.605 × (fCLOCK/20 MHz)
1.870 × (fCLOCK/20 MHz)
18.130 × (fCLOCK/20 MHz)
dB max
dB min
MHz min
MHz max
MHz min
MHz max
0.807 × (fCLOCK/20 MHz)
1.136 × (fCLOCK/20 MHz)
13.55 × (20 MHz/fCLOCK)
0
24.2 × (20 MHz/fCLOCK)
MHz max
MHz max
µs max
µs max
µs max
0.001
82.5
0
1.24 × (fCLOCK/20 MHz)
3.75 × (fCLOCK/20 MHz)
16.25 × (fCLOCK/20 MHz)
dB max
dB min
MHz min
MHz max
MHz min
MHz max
1.61 × (fCLOCK/20 MHz)
2.272 × (fCLOCK/20 MHz)
2.90 × (20 MHz/fCLOCK)
0
5.05 × (20 MHz/fCLOCK)
MHz max
MHz max
µs max
µs max
µs max
0.0005
85.5
0
2.491 × (fCLOCK/20 MHz)
7.519 × (fCLOCK/20 MHz)
12.481 × (fCLOCK/20 MHz)
dB max
dB min
MHz min
MHz max
MHz min
MHz max
3.231 × (fCLOCK/20 MHz)
4.535 × (fCLOCK/20 MHz)
0.80 × (20 MHz/fCLOCK)
0
1.40 × (20 MHz/fCLOCK)
MHz max
MHz max
µs max
µs max
µs max
13
(225 × (20 MHz/fCLOCK)) + tPROP
ns max
ns max
NOTES
1
To determine “overall” Absolute Group Delay and/or Settling Time inclusive of delay from the sigma-delta modulator, add Absolute Group Delay and/or Settling
Time pertaining to specific decimation mode to the Absolute Group Delay specified in 1 × decimation.
Specifications subject to change without notice.
REV. B
–5–
AD9260–Digital Filter Characteristics
1.0
NORMALIZED OUTPUT RESPONSE
0
MAGNITUDE – dB
–20
–40
–60
–80
–100
–120
0
0.2
0.4
0.6
0.8
FREQUENCY (NORMALIZED TO )
1.0
0.8
0.6
0.4
0.2
0
–0.2
–0.4
1.2
0
1.0
–20
0.8
–40
–60
–80
–100
–120
0
0.4
0.6
0.8
1.0
FREQUENCY (NORMALIZED TO )
0.2
0
1.2
10
0
20
30
40
50
60
70
80
90
100
110
CLOCK PERIODS – RELATIVE TO CLK
Figure 2b. 4× FIR Filter Impulse Response
0
NORMALIZED OUTPUT RESPONSE
1.0
–20
MAGNITUDE – dB
500
0.4
Figure 2a. 4× FIR Filter Frequency Response
–40
–60
–80
–100
–120
0
200
300
400
CLOCK PERIODS – RELATIVE TO CLK
0.6
–0.2
0.2
100
Figure 1b. 8× FIR Filter Impulse Response
NORMALIZED OUTPUT RESPONSE
MAGNITUDE – dB
Figure 1a. 8× FIR Filter Frequency Response
0
0.8
0.6
0.4
0.2
0
–0.2
0.2
0.4
0.6
0.8
FREQUENCY (NORMALIZED TO )
1.0
1.2
0
5
10
15
20
CLOCK PERIODS – RELATIVE TO CLK
Figure 3a. 2× FIR Filter Frequency Response
Figure 3b. 2× FIR Filter Impulse Response
–6–
REV. B
AD9260
Table I. Integer Filter Coefficients for First Stage Decimation
Filter (23-Tap Halfband FIR Filter)
Table III. Integer Filter Coefficients for Third Stage Decimation Filter (107-Tap Halfband FIR Filter)
Lower
Coefficient
Upper
Coefficient
Integer
Value
Lower
Coefficient
Upper
Coefficient
Integer
Value
H(1)
H(2)
H(3)
H(4)
H(5)
H(6)
H(7)
H(8)
H(9)
H(10)
H(11)
H(12)
H(23)
H(22)
H(21)
H(20)
H(19)
H(18)
H(17)
H(16)
H(15)
H(14)
H(13)
–1
0
13
0
–66
0
224
0
–642
0
2496
4048
H(1)
H(2)
H(3)
H(4)
H(5)
H(6)
H(7)
H(8)
H(9)
H(10)
H(11)
H(12)
H(13)
H(14)
H(15)
H(16)
H(17)
H(18)
H(19)
H(20)
H(21)
H(22)
H(23)
H(24)
H(25)
H(26)
H(27)
H(28)
H(29)
H(30)
H(31)
H(32)
H(33)
H(34)
H(35)
H(36)
H(37)
H(38)
H(39)
H(40)
H(41)
H(42)
H(43)
H(44)
H(45)
H(46)
H(47)
H(48)
H(49)
H(50)
H(51)
H(52)
H(53)
H(54)
H(107)
H(106)
H(105)
H(104)
H(103)
H(102)
H(101)
H(100)
H(99)
H(98)
H(97)
H(96)
H(95)
H(94)
H(93)
H(92)
H(91)
H(90)
H(89)
H(88)
H(87)
H(86)
H(85)
H(84)
H(83)
H(82)
H(81)
H(80)
H(79)
H(78)
H(77)
H(76)
H(75)
H(74)
H(73)
H(72)
H(71)
H(70)
H(69)
H(68)
H(67)
H(66)
H(65)
H(64)
H(63)
H(62)
H(61)
H(60)
H(59)
H(58)
H(57)
H(56)
H(55)
–1
0
2
0
–2
0
3
0
–3
0
1
0
3
0
–12
0
27
0
–50
0
85
0
–135
0
204
0
–297
0
420
0
–579
0
784
0
–1044
0
1376
0
–1797
0
2344
0
–3072
0
4089
0
–5624
0
8280
0
–14268
0
43520
68508
Table II. Integer Filter Coefficients for Second Stage Decimation Filter (43-Tap Halfband FIR Filter)
Lower
Coefficient
Upper
Coefficient
Integer
Value
H(1)
H(2)
H(3)
H(4)
H(5)
H(6)
H(7)
H(8)
H(9)
H(10)
H(11)
H(12)
H(13)
H(14)
H(15)
H(16)
H(17)
H(18)
H(19)
H(20)
H(21)
H(22)
H(43)
H(42)
H(41)
H(40)
H(39)
H(38)
H(37)
H(36)
H(35)
H(34)
H(33)
H(32)
H(31)
H(30)
H(29)
H(28)
H(27)
H(26)
H(25)
H(24)
H(23)
3
0
–12
0
35
0
–83
0
172
0
–324
0
572
0
–976
0
1680
0
–3204
0
10274
16274
NOTE: The composite filter undecimated coefficients (i.e.,
impulse response) in the 4× decimation mode can be determined
by convolving the first stage filter taps with a “zero stuffed”
version of the second stage filter taps (i.e., insert one zero between samples). Similarly, the composite filter coefficients in the
8× decimation mode can be determined by convolving the taps
of the composite 4× decimation mode (as previously determined) with a “zero stuffed” version of the third stage filter taps
(i.e., insert three zeros between samples).
REV. B
–7–
AD9260–SPECIFICATIONS
DIGITAL SPECIFICATIONS (AVDD = +5 V, DVDD = +5 V, T
MIN
to TMAX unless otherwise noted)
Parameter
AD9260
Units
1
CLOCK AND LOGIC INPUTS
High-Level Input Voltage
(DVDD = +5 V)
(DVDD = +3 V)
Low-Level Input Voltage
(DVDD = +5 V)
(DVDD = +3 V)
High-Level Input Current (VIN = DVDD)
Low-Level Input Current (VIN = 0 V)
Input Capacitance
+3.5
+2.1
V min
V max
+1.0
+0.9
± 10
± 10
5
V min
V max
µA max
µA max
pF typ
LOGIC OUTPUTS (with DRVDD = 5 V)
High-Level Output Voltage (IOH = 50 µA)
High-Level Output Voltage (IOH = 0.5 mA)
Low-Level Output Voltage2 (IOL = 0.3 mA)
Low-Level Output Voltage (IOL = 50 µA)
Output Capacitance
+4.5
+2.4
+0.4
+0.1
5
V min
V min
V max
V max
pF typ
LOGIC OUTPUTS (with DRVDD = 3 V)
High-Level Output Voltage (IOH = 50 µA)
Low-Level Output Voltage (IOL = 50 µA)
+2.4
+0.7
V min
V max
NOTES
1
Since CLK is referenced to AVDD, +5 V logic input levels only apply.
2
The AD9260 is not guaranteed to meet V OL = 0.4 V max for standard TTL load of I OL = 1.6 mA.
Specifications subject to change without notice.
S2
S1
tC
ANALOG INPUT
tCL
tCH
INPUT CLOCK
tDS
tDI
DATA OUTPUT
tOE
tH
DAV
tDAV
tOD
READ
CS
Figure 4a. Timing Diagram
tRES-DAV
tCLK-DAV
INPUT CLOCK
RESET
DAV
Figure 4b. RESET Timing Diagram
–8–
REV. B
AD9260
SWITCHING SPECIFICATIONS
(AVDD = +5 V, DVDD = +5 V, CL = 20 pF, TMIN to TMAX unless otherwise noted)
Parameters
Symbol
AD9260
Units
Clock Period
Data Available (DAV) Period
Data Invalid
Data Setup Time
Clock Pulsewidth High
Clock Pulsewidth Low
Data Hold Time
RESET to DAV Delay
CLOCK to DAV Delay
Three-State Output Disable Time
Three-State Output Enable Time
tC
tDAV
tDI
tDS
tCH
tCL
tH
tRES–DAV
tCLK–DAV
tOD
tOE
50
tC × Mode
40% tDAV
tDAV –tH–tDI
22.5
22.5
3.5
10
15
8
45
ns min
ns min
ns max
ns min
ns min
ns min
ns min
ns typ
ns typ
ns typ
ns typ
Specifications subject to change without notice.
ABSOLUTE MAXIMUM RATINGS*
Parameter
AVDD
DVDD
AVSS
AVDD
DRVDD
DRVSS
REFCOM
CLK, MODE, READ,
CS, RESET
Digital Outputs
VINA, VINB,
CML, BIAS
VREF
SENSE
CAPB, CAPT
Junction Temperature
Storage Temperature
Lead Temperature
(10 sec)
ORDERING GUIDE
With
Respect
to
Min
Max
Units
AVSS
DVSS
DVSS
DVDD
DRVSS
AVSS
AVSS
–0.3
–0.3
–0.3
–6.5
–0.3
–0.3
–0.3
+6.5
+6.5
+0.3
+6.5
+6.5
+0.3
+0.3
V
V
V
V
V
V
V
DVSS
DRVSS
–0.3
–0.3
DVDD + 0.3 V
DRVDD + 0.3 V
AVSS
AVSS
AVSS
AVSS
–0.3
–0.3
–0.3
–0.3
AVDD + 0.3
AVDD + 0.3
AVDD + 0.3
AVDD + 0.3
+150
+150
V
V
V
V
°C
°C
+300
°C
–65
Model
AD9260AS
AD9260EB
Temperature
Range
Package
Description
Package
Option*
–40°C to +85°C
44-Lead MQFP
Evaluation Board
S-44
*S = Metric Quad Flatpack.
THERMAL CHARACTERISTICS
Thermal Resistance
44-Lead MQFP
θJA = 53.2°C/W
θJC = 19°C/W
*Stresses above those listed under Absolute Maximum Ratings may cause permanent damage to the device. This is a stress rating only; 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 ratings
for extended periods may effect device reliability.
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 AD9260 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.
REV. B
–9–
WARNING!
ESD SENSITIVE DEVICE
AD9260
DEFINITIONS OF SPECIFICATION
APERTURE JITTER
INTEGRAL NONLINEARITY (INL)
Aperture jitter is the variation in aperture delay for successive
samples and is manifested as noise on the input to the A/D.
INL refers to the deviation of each individual code from a line
drawn from “negative full scale” through “positive full scale.”
The point used as “negative full scale” occurs 1/2 LSB before
the first code transition. “Positive full scale” is defined as a
level 1 1/2 LSB beyond the last code transition. The deviation
is measured from the middle of each particular code to the true
straight line.
SIGNAL-TO-NOISE AND DISTORTION (S/N+D, SINAD)
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.
DIFFERENTIAL NONLINEARITY (DNL, NO MISSING
CODES)
EFFECTIVE NUMBER OF BITS (ENOB)
For a sine wave, SINAD can be expressed in terms of the number of bits. Using the following formula,
An ideal ADC exhibits code transitions that are exactly 1 LSB
apart. DNL is the deviation from this ideal value. Guaranteed
no missing codes to 14-bit resolution indicates that all 16384
codes, respectively, must be present over all operating ranges.
N = (SINAD – 1.76)/6.02
NOTE: Conventional INL and DNL measurements don’t really
apply to Σ∆ converters: the DNL looks continually better if
longer data records are taken. For the AD9260, INL and DNL
numbers are given as representative.
ZERO ERROR
it is possible to get a measure of performance expressed as N,
the effective number of bits.
Thus, effective number of bits for a device for sine wave inputs
at a given input frequency can be calculated directly from its
measured SINAD.
TOTAL HARMONIC DISTORTION (THD)
The major carry transition should occur for an analog value
1/2 LSB below VINA = VINB. Zero error is defined as the
deviation of the actual transition from that point.
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.
GAIN ERROR
The first code transition should occur at an analog value
1/2 LSB above negative full scale. The last transition should
occur at an analog value 1 1/2 LSB below the nominal full scale.
Gain error is the deviation of the actual difference between first
and last code transitions and the ideal difference between first
and last code transitions.
SIGNAL-TO-NOISE RATIO (SNR)
SNR 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, excluding the first six harmonics and dc. The value
for SNR is expressed in decibels.
SPURIOUS FREE DYNAMIC RANGE (SFDR)
SFDR is the difference in dB between the rms amplitude of the
input signal and the peak spurious signal.
TEMPERATURE DRIFT
The temperature drift for zero error and gain error specifies the
maximum change from the initial (+25°C) value to the value at
TMIN or TMAX.
TWO-TONE SFDR
POWER SUPPLY REJECTION
The specification shows the maximum change in full scale from
the value with the supply at the minimum limit to the value with
the supply at its maximum limit.
The ratio of the rms value of either input tone to the rms value
of the peak spurious component. The peak spurious component
may or may not be an IMD product. May be reported in dBc
(i.e., degrades as signal level is lowered), or in dBFS (always
related back to converter full scale).
–10–
REV. B
AD9260
BIAS
MODE
CAPT
CAPB
AVSS
NC
CML
VINA
NC
VINB
AVDD
PIN CONFIGURATION
44 43 42 41 40 39 38 37 36 35 34
DVSS 1
33 REFCOM
PIN 1
IDENTIFIER
AVSS 2
32 VREF
DVDD 3
31 SENSE
AVDD 4
30 RESET
DRVSS 5
AD9260
29 AVSS
DRVDD 6
TOP VIEW
(Not to Scale)
28 AVDD
CLK 7
27 CS
READ 8
26 DAV
(LSB) BIT16 9
25 OTR
BIT15 10
24 BIT1 (MSB)
BIT14 11
23 BIT2
BIT3
BIT4
BIT5
BIT7
BIT6
BIT8
BIT9
BIT10
BIT11
BIT12
BIT13
12 13 14 15 16 17 18 19 20 21 22
NC = NO CONNECT
PIN FUNCTION DESCRIPTIONS
Pin No.
Name
Description
1
2, 29, 38
3
4, 28, 44
5
6
7
8
9
10–23
24
25
26
27
30
31
32
33
34
35
36
37
39
40, 43
41
42
DVSS
AVSS
DVDD
AVDD
DRVSS
DRVDD
CLK
READ
BIT16
BIT15–BIT2
BIT1
OTR
DAV
CS
RESET
SENSE
VREF
REFCOM
MODE
BIAS
CAPB
CAPT
CML
NC
VINA
VINB
Digital Ground.
Analog Ground.
+3 V to +5 V Digital Supply.
+5 V Analog Supply.
Digital Output Driver Ground.
+3 V to +5 V Digital Output Driver Supply.
Clock Input.
Part of DSP Interface—Pull Low to Disable Output Bits.
Least Significant Data Bit (LSB).
Data Output Bit.
Most Significant Data Bit (MSB).
Out of Range—Set When Converter or Filter Overflows.
Data Available.
Chip Select (CS): Active LOW.
RESET: Active LOW.
Reference Amplifier SENSE: Selects REF Level.
Input Span Select Reference I/O.
Reference Common.
Mode Select—Selects Decimation Mode.
Power Bias.
Noise Reduction Pin—Decouples Reference Level.
Noise Reduction Pin—Decouples Reference Level.
Common-Mode Level (AVDD/2.5).
No Connect (Ground for Shielding Purposes).
Analog Input Pin (+).
Analog Input Pin (–).
REV. B
–11–
AD9260–Typical Performance Characteristics
(AVDD = DVDD = DRVDD = +5.0 V, 4 V Input Span, Differential DC Coupled Input with CML = 2.0 V, fCLOCK = 20 MSPS, Full Bias)
0
0
–20
20MHz CLOCK
8 DECIMATION
–40
THD: –96dB
100kHz INPUT
–20
dB BELOW FULL SCALE
dB BELOW FULL SCALE
100kHz INPUT
–60
–80
–40
–80
–100
–120
–120
0.2
0.4
0.6
0.8
FREQUENCY – MHz
0
1.2
1.0
THD: –98dB
–60
–100
0
20MHz CLOCK
1 DECIMATION
1
2
3
4
5
6
FREQUENCY – MHz
7
8
9
10
Figure 8. Spectral Plot of the AD9260 at 100 kHz Input,
20 MHz Clock, Undecimated (20 MHz Output Data Rate)
Figure 5. Spectral Plot of the AD9260 at 100 kHz Input,
20 MHz Clock, 8 × OSR (2.5 MHz Output Data Rate)
0
110
100kHz INPUT
–12dBFS/TONE
–20
–40
106
WORST CASE SPUR – dBFS
dB BELOW FULL SCALE
20MHz CLOCK
4 DECIMATION
THD: –98dB
–60
–80
–100
102
–6.5dBFS/TONE
98
–26dBFS/TONE
–46dBFS/TONE
94
–120
0
0.5
1
1.5
FREQUENCY – MHz
2
90
2.5
Figure 6. Spectral Plot of the AD9260 at 100 kHz Input,
20 MHz Clock, 4 × OSR (5 MHz Output Data Rate)
0
0.2
0.4
0.6
FREQUENCY – MHz
0.8
1
Figure 9. Dual Tone SFDR vs. Input Frequency (F1 = F2,
(F1 – F2, Span = 10% Center Frequency, Mode = 8×)
0
0
DUAL-TONE TEST
100kHz INPUT
20MHz CLOCK
2 DECIMATION
–40
dB BELOW FULL SCALE
dB BELOW FULL SCALE
–20
THD: –98dB
–60
–80
–20
f1 = 1.0MHz
f2 = 975kHz
–40
20MHz CLOCK
8 DECIMATION
IM3: –94dB
–60
–80
–100
–100
–120
–120
0
0.5
1
1.5
2
2.5
3
3.5
FREQUENCY – MHz
4
4.5
5
0
Figure 7. Spectral Plot of the AD9260 at 100 kHz Input,
20 MHz Clock, 2 × OSR (10 MHz Output Data Rate)
0.2
0.4
0.6
0.8
FREQUENCY – MHz
1
1.2
Figure 10. Two-Tone Spectral Performance of the
AD9260 Given Inputs at 975 kHz and 1.0 MHz, 20 MHz
Clock, 8× Decimation
–12–
REV. B
AD9260
Typical AC Characterization Curves vs. Decimation Mode
(AVDD = DVDD = DRVDD = +5 V, 4 V Input Span, Differential DC Coupled Input with CML = 2 V, AIN = 0.5 dBFS Full Bias)
90
75
80
2 MODE
70
65
75
2 MODE
70
65
1 MODE
60
60
1 MODE
55
50
0.1
8 MODE
4 MODE
4 MODE
80
SINAD – dBFS
85
8 MODE
SINAD – dBFS
85
90
55
50
0.1
10
1
INPUT FREQUENCY – MHz
Figure 11. SINAD vs. Input Frequency (fCLOCK = 20 MSPS)1
1
INPUT FREQUENCY – MHz
10
Figure 14. SINAD vs. Input Frequency (fCLOCK = 10 MSPS)1
–70
–50
1 MODE
–75
1 MODE
–60
–80
–85
THD – dBFS
THD – dBFS
–70
–80
2 MODE
–90
2 MODE
–100
8 MODE
4 MODE
–105
–110
4 MODE
–100
–115
8 MODE
–110
0.1
–90
–95
1
INPUT FREQUENCY – MHz
–120
0.1
10
1
INPUT FREQUENCY – MHz
10
Figure 15. THD vs. Input Frequency (fCLOCK = 10 MSPS)
Figure 12. THD vs. Input Frequency (fCLOCK = 20 MSPS)
–70
–50
–75
1 MODE
–60
1 MODE
–80
–85
SFDR – dBFS
SFDR – dBFS
–70
–80
2 MODE
–90
–95
2 MODE
4 MODE
–100
8 MODE
–90
–105
–110
–100
4 MODE
–115
8 MODE
–110
0.1
1
INPUT FREQUENCY – MHz
–120
0.1
10
8× SINAD performance limited by noise contribution of input differential op
amp driver.
REV. B
10
Figure 16. SFDR vs. Input Frequency (fCLOCK = 10 MSPS)
Figure 13. SFDR vs. Input Frequency (fCLOCK = 20 MSPS)
1
1
INPUT FREQUENCY – MHz
–13–
AD9260
Typical AC Characterization Curves for 8 Mode
(AVDD = DVDD = DRVDD = +5 V, 4 V Input Span, Differential DC Coupled Input with CML = 2 V, Full Bias)
90
90
85
85
–0.5dBFS
80
–6.0dBFS
–0.5dBFS
–6.0dBFS
SINAD – dB
SINAD – dB
80
75
75
70
70
–20dBFS
–20dBFS
65
65
60
0.1
60
0.1
1
1
INPUT FREQUENCY – MHz
INPUT FREQUENCY – MHz
Figure 17. SINAD vs. Input Frequency (fCLOCK = 20 MSPS)1
Figure 20. SINAD vs. Input Frequency (fCLOCK = 10 MSPS)1
–70
–70
–75
–75
–20dBFS
–80
–80
–0.5dBFS
–90
–95
THD – dB
THD – dB
–85
–6.0dBFS
–20dBFS
–85
–90
–95
–6.0dBFS
–100
–0.5dBFS
–100
–105
–110
0.1
–105
0.1
1
1
INPUT FREQUENCY – MHz
INPUT FREQUENCY – MHz
Figure 21. THD vs. Input Frequency (fCLOCK = 10 MSPS)
Figure 18. THD vs. Input Frequency (fCLOCK = 20 MSPS)
105
105
100
100
–6.0dBFS
SFDR – dBc
SFDR – dBc
–6.0dBFS
95
–0.5dBFS
90
95
–0.5dBFS
90
85
85
–20dBFS
80
0.1
80
0.1
1
1
INPUT FREQUENCY – MHz
INPUT FREQUENCY – MHz
Figure 22. SFDR vs. Input Frequency (fCLOCK = 10 MSPS)
Figure 19. SFDR vs. Input Frequency (fCLOCK = 20 MSPS)
1
–20dBFS
SINAD performance limited by noise contribution of input differential op amp
driver.
–14–
REV. B
AD9260
Typical AC Characterization Curves for 4 Mode
(AVDD = DVDD = DRVDD = +5 V, 4 V Input Span, Differential DC Coupled Input with CML = 2 V, Full Bias)
90
90
85
85
–0.5dBFS
–0.5dBFS
80
SINAD – dB
SINAD – dB
80
75
–6.0dBFS
70
65
–6.0dBFS
75
70
–20dBFS
60
65
55
–20dBFS
50
0.1
1
INPUT FREQUENCY – MHz
60
0.1
10
1
INPUT FREQUENCY – MHz
Figure 26. SINAD vs. Input Frequency (fCLOCK = 10 MSPS)
Figure 23. SINAD vs. Input Frequency (fCLOCK = 20 MSPS)
–70
–70
–75
–75
–20dBFS
–80
–80
–85
–85
THD – dB
THD – dB
–0.5dBFS
–0.5dBFS
–90
–20dBFS
–90
–95
–95
–6.0dBFS
–100
–100
–105
–105
–110
0.1
1
INPUT FREQUENCY – MHz
–110
0.1
10
Figure 27. THD vs. Input Frequency (fCLOCK = 10 MSPS)
110
110
105
100
–6.0dBFS
100
SFDR – dBc
–0.5dBFS
SFDR – dBc
105
95
85
–20dBFS
–0.5dBFS
–20dBFS
1
INPUT FREQUENCY – MHz
80
0.1
10
1
INPUT FREQUENCY – MHz
Figure 28. SFDR vs. Input Frequency (fCLOCK = 10 MSPS)
Figure 25. SFDR vs. Input Frequency (fCLOCK = 20 MSPS)
REV. B
–6.0dBFS
95
90
90
80
0.1
1
INPUT FREQUENCY – MHz
Figure 24. THD vs. Input Frequency (fCLOCK = 20 MSPS)
85
–6.0dBFS
–15–
AD9260
Typical AC Characterization Curves for 2 Mode
(AVDD = DVDD = DRVDD = +5 V, 4 V Input Span, Differential DC Coupled Input with CML = 2 V, Full Bias)
80
80
75
70
–0.5dBFS
70
–6.0dBFS
SINAD – dB
SINAD – dB
75
–5.0dBFS
65
65
60
60
55
–20dBFS
55
–20dBFS
50
50
0.1
1
INPUT FREQUENCY – MHz
–60
–65
–65
–70
–20dBFS
–75
THD – dB
–0.5dBFS
–75
–80
–80
–20dBFS
–85
–85
–90
–90
–0.5dBFS
–95
–100
0.1
10
Figure 32. SINAD vs. Input Frequency (fCLOCK = 10 MSPS)
–60
–70
1
INPUT FREQUENCY – MHz
0.1
10
Figure 29. SINAD vs. Input Frequency (fCLOCK = 20 MSPS)
THD – dB
–6.0dBFS
–6.0dBFS
–95
–6.0dBFS
1.0
INPUT FREQUENCY – MHz
–100
0.1
10
1
INPUT FREQUENCY – MHz
10
Figure 33. THD vs. Input Frequency (fCLOCK = 10 MSPS)
Figure 30. THD vs. Input Frequency (fCLOCK = 20 MSPS)
100
100
95
95
–6.0dBFS
90
SFDR – dBc
SFDR – dBc
90
–6.0dBFS
85
–0.5dBFS
–0.5dBFS
85
–20dBFS
80
80
75
75
–20dBFS
70
0.1
1
INPUT FREQUENCY – MHz
70
0.1
10
1
INPUT FREQUENCY – MHz
10
Figure 34. SFDR vs. Input Frequency (fCLOCK = 10 MSPS)
Figure 31. SFDR vs. Input Frequency (fCLOCK = 20 MSPS)
–16–
REV. B
AD9260
Typical AC Characterization Curves for 1 Mode
(AVDD = DVDD = DRVDD = +5 V, 4 V Input Span, Differential DC Coupled Input with CML = 2 V, Full Bias)
70
70
65
65
–0.5dBFS
–0.5dBFS
60
SINAD – dB
SINAD – dB
60
–6.0dBFS
55
–6.0dBFS
55
50
50
45
45
–20dBFS
–20dBFS
40
0.1
1
INPUT FREQUENCY – MHz
40
0.1
10
Figure 35. SINAD vs. Input Frequency (fCLOCK = 20 MSPS)
1
INPUT FREQUENCY – MHz
10
Figure 38. SINAD vs. Input Frequency (fCLOCK = 10 MSPS)
–55
–55
–0.5dBFS
–60
–60
–20dBFS
–65
–65
–20dB
–70
–6.0dBFS
THD – dBc
THD – dB
–70
–75
–80
–75
–80
–0.5dBFS
–85
–85
–90
–90
–95
–95
–6.0dBFS
–100
0.1
1
INPUT FREQUENCY – MHz
–100
0.1
10
Figure 36. THD vs. Input Frequency (fCLOCK = 20 MSPS)
100
95
95
–0.5dBFS
90
75
70
65
–6.0dBFS
75
70
–20dBFS
60
55
55
1
INPUT FREQUENCY – MHz
50
0.1
10
Figure 37. SFDR vs. Input Frequency (fCLOCK = 20 MSPS)
REV. B
80
65
–20dBFS
60
50
0.1
–0.5dBFS
85
–6.0dBFS
SFDR – dBc
SDFR – dBc
85
80
10
Figure 39. THD vs. Input Frequency (fCLOCK = 10 MSPS)
100
90
1
INPUT FREQUENCY – MHz
1
INPUT FREQUENCY – MHz
10
Figure 40. SFDR vs. Input Frequency (fCLOCK = 10 MSPS)
–17–
AD9260
Typical AC Characterization Curves
(AVDD = DVDD = DRVDD = +5 V, 4 V Input Span, AIN = –0.5 dBFS, Differential DC Coupled Input with CML = 2 V)
–60
100
FULL BIAS
95
–65
90
–70
80
HALF BIAS
THD – dBc
SFDR – dBFS
85
75
70
QUARTER BIAS
–75
FIN = 1MHz, 2 MODE
–80
–85
65
FIN = 100kHz, 8 MODE
–90
60
–95
55
50
2
5
10
15
CLOCK FREQUENCY – MHz
–100
1.0
20
Figure 41. SFDR vs. Clock Rate (fIN = 100 kHz in 8 × Mode)
1.2
1.4
1.6
1.8 2.0
2.2
2.4
2.6
COMMON MODE INPUT LEVEL – Volts
2.8
3.0
Figure 44. THD vs. Common-Mode Input Level (CML)
–40
100
FULL BIAS
–50
FS = 20MHz
HALF BIAS
CMR – dB
SFDR – dBFS
80
60
QUARTER BIAS
–60
FS = 10MHz
–70
40
FS = 5MHz
–80
20
–90
1k
0
5
10
20
15
25
10k
100k
1M
INPUT FREQUENCY – Hz
CLOCK FREQUENCY – MHz
Figure 42. SFDR vs. Clock Rate (fIN = 500 kHz in 4 × Mode)
10M
100M
Figure 45. CMR vs. Input Frequency (VCML = 2 V p-p, 1×
Mode)
100
100
4V SPAN SNR-8 MODE
FULL BIAS
4V SPAN SFDR-2 MODE
95
1.6V SPAN SNR-8 MODE
80
SFDR – dBFS
SFDR – dBFS
1.6V SPAN SFDR-2 MODE
HALF BIAS
60
40
90
85
QUARTER BIAS
80
20
0
5
10
15
20
CLOCK FREQUENCY – MHz
75
25
Figure 43. SFDR vs. Clock Rate (fIN = 1.0 MHz in 2× Mode)
0
0.2
0.4
0.6
0.8
1.0
FREQUENCY – MHz
1.2
1.4
1.6
Figure 46. 4 V vs. 1.6 V Span SNR/SFDR (fCLOCK = 20 MSPS)
–18–
REV. B
AD9260
Additional AC Characterization Curves
(AVDD = DVDD = DRVDD = +5 V, 4 V Input Span, AIN = –0.5 dBFS, Differential DC Coupled Input with CML = 2 V, Full Bias, unless otherwise noted)
120
120
115
20MSPS-dBFS
FULL BIAS
20 MSPS
FULL BIAS
SFDR – dBFS
WORST SPUR – dBc and dBFS
110
10 MSPS
FULL BIAS
110
105
100
95
20 MSPS
HALF BIAS
90
10 MSPS
HALF BIAS
85
80
–50
100
10MSPS-dBFS
HALF BIAS
90
20MSPS-dBc
FULL BIAS
10MSPS-dBc
HALF BIAS
80
70
60
–45
–40
–35
–30 –25 –20
AIN – dBFS
–15
–10
–5
50
–60
0
Figure 47. Single-Tone SFDR vs. Amplitude (fIN =100 kHz,
8× Mode)
–50
–40
–30
AIN – dBFS
–20
–10
0
Figure 50. Two-Tone SFDR (F1 = 475 kHz, F2 = 525 MHz,
8 × Mode)
110
120
FULL BIAS-dBFS
105
110
WORST SPUR – dBc and dBFS
10 MSPS
FULL BIAS
SFDR – dBFS
100
95
20 MSPS
FULL BIAS
10 MSPS
HALF BIAS
90
85
80
–50
–45
–40
–35
–30 –25 –20
AIN – dBFS
–15
–10
–5
HALF BIAS-dBc
70
–50
–40
–30
AIN – dBFS
–20
–10
0
Figure 51. Two-Tone SFDR (F1 = 0.95 kHz, F2 = 1.05 MHz,
8 × Mode 20 MSPS)
120
10 MSPS
HALF BIAS
10 MSPS
FULL BIAS
110
WORST SPUR – dBc and dBFS
105
100
SFDR – dBFS
FULL BIAS-dBc
80
50
–60
0
110
20 MSPS
FULL BIAS
95
90
85
dBFS
100
dBc
90
80
70
60
–45
–40
–35
–30 –25 –20
AIN – dBFS
–15
–10
–5
50
–60
0
Figure 49. Single-Tone SFDR vs. Amplitude (fIN = 500 kHz,
2 × Mode)
REV. B
HALF BIAS-dBFS
90
60
Figure 48. Single-Tone SFDR vs. Amplitude (fIN =1.0 MHz,
2× Mode)
80
–50
100
–50
–40
–30
AIN – dBFS
–20
–10
0
Figure 52. Two-Tone SFDR (F1 = 1.9 MHz, F2 = 2.1 MHz,
4 × Mode 20 MSPS)
–19–
AD9260
+
–
VIN
+
–
5B
DAC1
INT1
+
–
INT2
5B
ADC
+
–
16
5B
DAC
3B
ADC
+
–
4
3B
DAC
3B
ADC
3B
DAC
4
4B
ADC
PIPELINE CORRECTION LOGIC
5B
DAC2
8 LSBs
SHUFFLE
MOUT
Z–D
++
LSB
DIFFERENTIATOR
COUT
CONTROL/TEST
LOGIC
HALF-BAND
DECIMATION FILTER STAGE 1
BANDGAP
REFERENCE
HALF-BAND
DECIMATION FILTER STAGE 2
REFERENCE
BUFFER
HALF-BAND
DECIMATION FILTER STAGE 3
OUTPUT BITS
Figure 53. Simplified Block Diagram
THEORY OF OPERATION
The AD9260 utilizes a new analog-to-digital converter architecture to combine sigma-delta techniques with a high-speed,
pipelined A/D converter. This topology allows the AD9260 to
offer the high dynamic range associated with sigma-delta converters while maintaining very wide input signal bandwidth
(1.25 MHz) at a very modest 8× oversampling ratio. Figure 53
provides a block diagram of the AD9260. The differential
analog input is fed into a second order, multibit sigma-delta
modulator. This modulator features a 5-bit flash quantizer and
5-bit feedback. In addition, a 12-bit pipelined A/D quantizes
the input to the 5-bit flash to greater accuracy. A special digital
modulation loop combines the output of the 12-bit pipelined
A/D with the delayed output of the 5-bit flash to produce the
equivalent response of a second order loop with a 12-bit
quantizer and 12-bit feedback. The combination of a second
order loop and multibit feedback provides inherent stability:
the AD9260 is not prone to idle tones or full-scale idiosyncracies sometimes associated with higher order single bit sigmadelta modulators.
The output of this 12-bit modulator is fed into the digital decimation filter. The voltage level on the MODE pin establishes
the configuration for the digital filter. The user may bring the
data out undecimated (at the clock rate), or at a decimation
factor of 2×, 4×, or a full 8×. The spectra for these four cases
are shown in Figures 5, 6, 7 and 8, all for a 100 kHz full-scale
input and 20 MHz clock. The spectra of the undecimated
output clearly shows the second order shaping characteristic of
the quantization noise as it rises at frequencies above 1.25 MHz.
The digital output driver register of the AD9260 features both
READ and CHIP SELECT pins to allow easy interfacing. The
digital supply of the AD9260 is designed to operate over a
2.7 V to 5.25 V supply range, though 3 V supplies are recommended to minimize digital noise on the board. A DATA
AVAILABLE pin allows the user to easily synchronize to the
converter’s decimated output data rate. OUT-OF-RANGE
(OTR) indication is given for an overflow in the pipelined A/D
converter or digital filters. A RESETB function is provided to
synchronize the converter’s decimated data and clear any overflow condition in the analog integrators.
An on-chip reference and reference buffer are included on the
AD9260. The reference can be configured in either a 2.5 V
mode (providing a 4 V pk-pk differential input full scale), a 1 V
mode (providing a 1.6 V pk-pk differential input full scale), or
programmed with an external resistor divider to provide any
voltage level between 1 V and 2.5 V. However, optimum noise and
distortion performance for the AD9260 can only be achieved with a
2.5 V reference as shown in Figure 46.
For users wishing to operate the part at reduced clock frequencies, the bias current of the AD9260 is designed to be scalable.
This scaling is accomplished through use of the proper external
resistor tied to the BIAS pin: the power can be reduced roughly
proportionately to clock frequency by as much as 75% (for clock
rates of 5 MHz). Refer to Figures 41–43 and 47–51 for characterization curves showing performance tradeoffs.
ANALOG INPUT AND REFERENCE OVERVIEW
The on-chip decimation filter provides excellent stopband rejection to suppress any stray input signal between 1.25 MHz and
18.75 MHz, substantially easing the requirements on any antialiasing filter for the analog input path. The decimation filters
are integrated with symmetric FIR filter structures, providing a
linear phase response and excellent passband flatness.
Figure 54, a simplified model of the AD9260, highlights the
relationship between the analog inputs, VINA, VINB and the
reference voltage VREF. Like the voltage applied to the top of
the resistor ladder in a flash A/D converter, the value VREF
defines the maximum input voltage to the A/D converter. An
internal reference buffer in the AD9260 scales the reference
voltage VREF before it is applied internally to the AD9260
–20–
REV. B
AD9260
A/D core. The scale factor of this reference buffer is 0.8. Consequently, the maximum input voltage to the A/D core is +0.8 ×
VREF. The minimum input voltage to the A/D core is automatically defined to be –0.8 × VREF. With this scale factor, the
maximum differential input span of 4 V p-p is obtained with a
VREF voltage of 2.5 V. A smaller differential input span may be
obtained by using a VREF voltage of less than 2.5 V at the
expense of ac performance (refer to Figure 46).
+0.8VREF
VINA
+
–
16
ANALOG INPUT OPERATION
The analog input structure of the AD9260 is optimized to meet
the performance requirements for some of the most demanding
communication and data acquisition applications. This input
structure is composed of a switched-capacitor network that
samples the input signal applied to pins VINA and VINB on
every rising edge of the CLK pin. The input switched capacitors are charged to the input voltage during each period of
CLK. The resulting charge, q, on these capacitors is equal to
C × VIN, where C is the input capacitor. The change in charge
on these capacitors, delta q, as the capacitors are charged from a
previous sample of the input signal to the next sample, is approximated in the following equation,
A/D CORE
delta q ~ C × deltaVN = C × (VN – VN–2)
VINB
where VN represents the present sample of the input signal and
VN–2 represents the sample taken two clock cycles earlier. The
average current flow into the input (provided from an external
source) is given in the following equation,
–0.8VREF
Figure 54. Simplified Input Model
I = delta q/T ~ C × (VN – VN–2) × fCLOCK
INPUT SPAN
SS3
(1)
SS1
CS1
SH1
VINA
defines the output of the differential input stage and provides
the input to the A/D core.
CPA1
The voltage, VCORE, must satisfy the condition,
–0.8 × VREF ≤ VCORE ≤ +0.8 × VREF
(5)
where T represents the period of CLK and fCLOCK represents the
frequency of CLK. Equations 4 and 5 provide simplifying approximations of the operation of the analog input structure of
the AD9260. A more exact, detailed description and analysis of
the input operation is provided below.
The AD9260 is implemented with a differential input structure.
This structure allows the common-mode level (average voltage
of the two input pins) of the input signal to be varied independently of the input span of the converter over a wide range, as
shown in Figure 44. Specifically, the input to the A/D core is
the difference of the voltages applied at the VINA and VINB
input pins. Therefore, the equation,
VCORE = VINA–VINB
(4)
CPB1
SS2
SS4
CS2
ANALOG
MODULATOR
SH2
VINB
(2)
CPA2
CPB2
where VREF is the voltage at the VREF pin.
SH3
INPUT COMPLIANCE RANGE
SH4
In addition to the limitations on the differential span of the
input signal indicated in Equation 2, an additional limitation is
placed on the inputs by the analog input structure of the AD9260.
The analog input structure bounds the valid operating range for
VINA and VINB. The condition,
AVSS +0.5 V < VINA < AVDD – 0.5 V
AVSS +0.5 V < VINB < AVDD + 0.5 V
(3)
where AVSS is nominally 0 V and AVDD is nominally +5 V,
defines this requirement. Thus the valid inputs for VINA and
VINB are any combination that satisfies both Equations 2 and
3. Note, the clock clamping method used in the differential
driver circuit shown in Figure 57 is sufficient for protecting the
AD9260 in an undervoltage condition.
For additional information showing the relationships between
VINA, VINB, VREF and the digital output of the AD9260, see
Table V.
Refer to Table IV for a summary of the various analog input
and reference configurations.
Figure 55. Detailed Analog Input Structure
Figure 55 illustrates the analog input structure of the AD9260.
For the moment, ignore the presence of the parasitic capacitors
CPA and CPB. The effects of these parasitic capacitors will be
discussed near the end of this section. The switched capacitors,
CS1 and CS2, sample the input voltages applied on pins VINA
and VINB. These capacitors are connected to input pins VINA
and VINB when CLK is low. When CLK rises, a sample of the
input signal is taken on capacitors CS1 and CS2. When CLK is
high, capacitors CS1 and CS2 are connected to the Analog
Modulator. The modulator precharges capacitors CS1 and CS2
to minimize the amount of charge required from any circuit
used in combination with the AD9260 to drive input pins VINA
and VINB. This reduces the input drive requirements of the
analog circuitry driving pins VINA and VINB. The Analog
Modulator precharges the voltages across capacitors CS1 and
CS2, approximately equal to a delayed version of the input
signal. When capacitors CS1 and CS2 are connected to input
pins VINA and VINB, the differential charge, Q(n), on these
capacitors is given in the following equation,
Q(n) = q1 – q2 = CS × VCORE
REV. B
–21–
(6)
AD9260
where q1 and q2 are the individual charges stored on capacitors
CS1 and CS2 respectively, and CS is the capacitance value of
CS1 and CS2. When capacitors CS1 and CS2 are connected to
the Analog Modulator during the preceding “precharge” clock
phase, the capacitors are precharged equal to an approximation
of a previous sample of the input signal. Consequently the
differential charge on these capacitors while CLK is high is
given in the following equation,
Q(n–1) = CS × VCORE(delay) + CS × Vdelta
(7)
where VCORE(delay) is the value of VCORE sampled during a
previous period of CLK, and Vdelta is the sigma-delta error
voltage left on the capacitors. Vdelta is a natural artifact of the
sigma-delta feedback techniques utilized in the Analog Modulator of the AD9260. It is a small random voltage term that
changes every clock period and varies from 0 to ± 0.05 × VREF.
The analog circuitry used to drive the input pins of the AD9260
must respond to the charge glitch that occurs when capacitors
CS1 and CS2 are connected to input pins VINA and VINB. This
circuitry must provide additional charge, qdelta, to capacitors
CS1 and CS2, which is the difference between the precharged
value, Q(n–1), and the new value, Q(n), as given in the following equation,
and CS2 when they are connected to input Pins VINA and
VINB. The nonlinear junction capacitance of Cpb1 and Cpb2
cause charge glitch energy that is nonlinearily related to the
input signal. Therefore, linear settling is difficult to achieve
unless the input source completely settles during one-half
period of CLK. A portion of the glitch impulse energy “kicked”
back at the source is not linearly related to the input signal.
Therefore, the best way to ensure that the input signal settles
linearly is to use wide bandwidth circuitry, which settles as
completely as possible from the glitch during one-half period of
the CLK.
The AD9260 utilizes a proprietary clock-boosted boot-strapping
technique to reduce the nonlinear parasitic capacitances of the
internal CMOS switches. This technique improves the linearity
of the input switches and reduces the nonlinear parasitic capacitance. Thus, this technique reduces the nonlinear glitch energy.
The capacitance values for the input capacitors and parasitic
capacitors for the input structure of the AD9260, as illustrated
in Figure 55, are listed as follows.
Qdelta = Q(n) – Q(n–1)
(8)
CS = 3.2 pF, Cpa = 6 pF, Cpb = 1 pF (where CS is the capacitance value of capacitors CS1 and CS2, Cpa is the value of
capacitors Cpa1 and Cpa2, and Cpb is the value of capacitors
Cpb1 and Cpb2). The total capacitance at each input pin is
CIN = CS + Cpa + Cpb = 10.2 pF.
Qdelta = CS × [VCORE–VCORE(delay) + Vdelta]
(9)
Input Driver Considerations
The optimum noise and distortion performance of the AD9260 can
ONLY be achieved when the AD9260 is driven differentially with a
4 V input span . Since not all applications have a signal preconditioned for differential operation, there is often a need to perform a single-ended-to-differential conversion. In the case of the
AD9260, a single-ended-to-differential conversion is best realized
using a differential op amp driver. Although a transformer will
perform a similar function for ac signals, its usefulness is precluded by its inability to directly drive the AD9260 and thus the
additional requirement of an active low noise, low distortion
buffer stage.
DRIVING THE INPUT
Transient Response
The charge glitch occurs once at the beginning of every period
of the input CLK (falling edge), and the sample is taken on
capacitors CS1 and CS2 exactly one-half period later (rising
edge). Figure 56 presents a typical input waveform applied to
input Pins VINA and VINB of the AD9260.
TRACK SAMPLE TRACK SAMPLE TRACK SAMPLE TRACK SAMPLE
CLOCK
Single-Ended-to-Differential Op Amp Driver
VINA-VINB
Figure 56. Typical Input Waveform
Figure 56 illustrates the effect of the charge glitch when a source
with nonzero output impedance is used to drive the input pins.
This source must be capable of settling from the charge glitch in
one-half period of the CLK. Unfortunately, the MOS switches
used in any CMOS-switched capacitor circuit (including those
in the AD9260) include nonlinear parasitic junction capacitances connected to their terminals. Figure 55 also illustrates
the parasitic capacitances, Cpa1, Cpb1, Cpa2 and Cpb2, associated with the input switches.
Parasitic capacitor Cpa1 and Cpa2 are always connected to Pins
VINA and VINB and therefore do not contribute to the glitch
energy. Parasitic capacitors Cpb1 and Cpb2, on the other hand,
cause a charge glitch that adds to that of input capacitors CS1
There are two single-ended-to-differential op amp driver circuits useful for driving the AD9260. The first circuit, shown in
Figure 57, uses the AD8138 and represents the best choice in
most applications. The AD8138 is a low-distortion differential
ADC driver designed to convert a ground-referenced singleended input signal to a differential output signal with a specified
common-mode level for dc-coupling applications. It is capable
of maintaining the typical THD and SFDR performance of the
AD9260 with only a slight degradation in its noise performance
in the 8× mode (i.e., SNR of 85 dB–86 dB).
In this application, the AD8138 is configured for unity gain and
its common-mode output level is set to 2.5 V (i.e., VREF of the
AD9260) to maximize its output headroom while operating from a
single supply. Note, single-supply operation has the benefit of
not requiring an input protection network for the AD9260 in
dc-coupled applications. A simple R-C network at the output is
used to filter out high-frequency noise from the AD8138. Recall,
the AD9260’s small signal bandwidth is 75 MHz, hence any
noise falling within the baseband bandwidth of the AD9260
defined by its sample and decimation rate, as well as “images”
of its baseband response occurring at multiples of the sample
rate, will degrade its overall noise performance.
–22–
REV. B
AD9260
R
499
499
50
VIN
VINA
+5V
VCML-VIN
R
VINA
AD9260
AD8138
R
CC
100pF
R
VIN
CF
50
VCML-VIN
VINB
499
499
R
CS
100pF
CF
AD9260
CD
100pF
50
50
VINB
R
CC
100pF
VREF
10F
50
50
CS
100pF
0.1F
R
R
AD817
Figure 57. AD8138 Single-Ended Differential ADC Driver
CML
The second driver circuit, shown in Figure 58, can provide slightly
enhanced noise performance relative to the AD8138, assuming
low-noise, high-speed op amps are used. This differential op amp
driver circuit is configured to convert and level-shift a 2 V p-p
single-ended, ground-referenced signal to a 4 V p-p differential
signal centered at the common-mode level of the AD9260. The
circuit is based on two op amps that are configured as matched
unity gain difference amplifiers. The single-ended input signal is
applied to opposing inputs of the difference amplifiers, thus
providing differential outputs. The common-mode offset voltage
is applied to the noninverting resistor leg of each difference amplifier providing the required offset voltage. This offset voltage is
derived from the common-mode level (CML) pin of the AD9260
via a low output impedance buffer amplifier capable of driving a
1 µF capacitive load. The common-mode offset can be varied
over a 1.8 V to 2.5 V span without any serious degradation in
distortion performance as shown in Figure 44, thus providing
some flexibility in improving output compression distortion from
some ± 5 op amps with limited positive voltage swing.
To protect the AD9260 from an undervoltage fault condition
from op amps specified for ± 5 V operation, two 50 Ω series
resistors and a diode to AGND are inserted between each op
amp output and the AD9260 inputs. The AD9260 will inherently
be protected against any overvoltage condition if the op amps
share the same positive power supply (i.e., AVDD) as the AD9260.
Note, the gain accuracy and common-mode rejection of each difference amplifier in this driver circuit can be enhanced by using
a matched thin-film resistor network (i.e., Ohmtek ORNA5000F)
for the op amps. Resistor values should be 500 Ω or less to maintain the lowest possible noise.
The noise performance of each unity gain differential driver
circuit is limited by its inherent noise gain of two. For unity gain
op amps ONLY, the noise gain can be reduced from two to one
1.0F
0.1F
Figure 58. DC-Coupled Differential Driver with
Level-Shifting
beyond the input signals passband by adding a shunt capacitor,
CF, across each op amp’s feedback resistor. This will essentially
establish a low-pass filter which reduces the noise gain to one
beyond the filter’s f–3 dB while simultaneously bandlimiting the
input signal to f–3 dB. Note, the pole established by this filter can
also be used as the real pole of an antialiasing filter. Since the
noise contribution of two op amps from the same product family
are typically equal but uncorrelated, the total output-referred
noise of each op amp will add root-sum square leading to a
further 3 dB degradation in the circuit’s noise performance.
Further out-of-band noise reduction can be realized with the
addition of single-ended and differential capacitors, CS and CD.
The distortion and noise performance of the two op amps
within the signal path are critical in achieving the AD9260’s
optimum performance. Low noise op amps capable of providing
greater than 85 dB THD at 1 MHz while swinging over a 1 V to
3 V range are a rare commodity, yet should only be considered.
The AD9632 op amp was found to provide superb distortion
performance in this circuit due to its ability to maintain excellent distortion performance over a wide bandwidth while swinging over a 1 V to 3 V range. Since the AD9632 is gain-of-two or
greater stable, the use of the noise reduction shunt capacitors
discussed above was prohibited thus degrading its noise performance slightly (1 dB–2 dB) when compared to the OPA642.
Note, the majority of the AD9260 test and characterization data
presented in this data sheet was taken using the AD9632 op
amp in this dc coupled driver circuit. This driver circuit is also
provided on the AD9260 evaluation board since the AD8138
was unreleased at that time.
Table IV. Reference Configuration Summary
Reference
Operating Mode
Input Span (VINA–VINB)
(V p-p)
Required VREF
(V)
INTERNAL
INTERNAL
INTERNAL
1.6
4.0
1.6 ≤ SPAN ≤ 4.0 and
SPAN = 1.6 × VREF
1.6 ≤ SPAN ≤ 4.0
1
2.5
1 ≤ VREF ≤ 2.5 and
VREF = (1+R1/R2)
1 ≤ VREF ≤ 2.5
EXTERNAL
REV. B
–23–
Connect
To
SENSE
SENSE
R1
R2
SENSE
VREF
VREF
REFCOM
VREF and SENSE
SENSE and REFCOM
AVDD
EXT. REF.
AD9260
The outputs of each op amp are ac coupled via a small series
resistor and capacitor (i.e., 50 Ω and 0.1 µF) to the respective
inputs of the AD9260. Similar to the dc coupled driver, further
out-of-band noise reduction can be realized with the addition of
100 pF single-ended and differential capacitors, CS and CD.
The lower-cutoff frequency of this ac coupled circuit is determined by RC and CC in which RC is tied to the common-mode
level pin, CML, of the AD9260 for proper biasing of the inputs.
Although the OPA642 was found to provide the lowest overall
noise and distortion performance (i.e., 88.8 dB and 96 dB
THD @ 100 kHz), the AD8055 (or dual AD8056) suffered
only a 0.5 dB to 1.5 dB degradation in overall performance. It
is worth noting that given the high-level of performance attainable
by the AD9260, special consideration must be given to both the
quality of the test equipment and test setup in its evaluation.
TO A/D
5k
CAPT
6.25k
6.25k
5k
DISABLE
A2
CAPB
LOGIC
– +
1V
VREF
A1
7.5k
AD9260
Common-Mode Level
SENSE
The CML pin is an internal analog bias point used internally by
the AD9260. This pin must be decoupled to analog ground
with at least a 0.1 µF capacitor as shown in Figure 59. The dc
level of CML is approximately AVDD/2.5. This voltage should
be buffered if it is to be used for any external biasing.
DISABLE
A1
LOGIC
5k
REFCOM
Note: the common-mode voltage of the input signal applied to
the AD9260 need not be at the exact same level as CML. While
this level is recommended for optimal performance, the AD9260 is
tolerant of a range of input common-mode voltages around
AVDD/2.5.
CML
0.1F
A2
AD9260
Figure 59. CML Decoupling
REFERENCE OPERATION
The AD9260 contains an onboard bandgap reference and internal reference buffer amplifier. The onboard reference provides a
pin-strappable option to generate either a 1 V or 2.5 V output.
With the addition of two external resistors, the user can generate
reference voltages other than 1 V and 2.5 V. Another alternative is to use an external reference for designs requiring enhanced accuracy and/or drift performance. See Table IV for a
summary of the pin-strapping options for the AD9260 reference
configurations. Note, the optimum noise and distortion can only be
achieved with a 2.5 V reference.
Figure 60 shows a simplified model of the internal voltage reference of the AD9260. A pin-strappable reference amplifier
buffers a 1 V fixed reference. The output from the reference
amplifier, A1, appears on the VREF pin and MUST be decoupled with 0.1 µF and 10 µF capacitor to REFCOM. The
voltage on the VREF pin determines the full-scale input span of
the A/D. This input span equals:
Full-Scale Input Span = 1.6 × VREF
The voltage appearing at the VREF pin, as well as the state of
the internal reference amplifier, A1, are determined by the voltage appearing at the SENSE pin. The logic circuitry contains
two comparators that monitor the voltage at the SENSE pin.
The comparator with the lowest set point (approximately 0.3 V)
Figure 60. Simplified Reference
controls the position of the switch within the feedback path of
A1. If the SENSE pin is tied to REFCOM, the switch is connected to the internal resistor network, thus providing a VREF
of 2.5 V. If the SENSE pin is tied to the VREF pin via a short
or resistor, the switch is connected to the SENSE pin. A short
will provide a VREF of 1.0 V while an external resistor network
will provide an alternative VREF SPAN between 1.0 V and
2.5 V. The external resistor network may, for example, be
implemented as a resistor divider circuit. This divider circuit
could consist of a resistor (R1) connected between VREF and
SENSE and another resistor (R2) connected between SENSE
and REFCOM. The other comparator controls internal circuitry that will disable the reference amplifier if the SENSE pin
is tied to AVDD. Disabling the reference amplifier allows the
VREF pin to be driven by an external voltage reference.
The reference buffer circuit, level shifts the reference to an
appropriate common-mode voltage for use by the internal circuitry. The on-chip buffer provides the low impedance necessary for driving the internal switched capacitor circuits and
eliminates the need for an external buffer op amp.
The actual reference voltages used by the internal circuitry of
the AD9260 appear on the CAPT and CAPB pins. If VREF is
configured for 2.5 V, thus providing a 4 V full-scale input span,
the voltages appear at CAPT and CAPB are 3.0 V and 1.0 V
respectively. For proper operation when using the internal or an
external reference, it is necessary to add a capacitor network to
decouple the CAPT and CAPB pins. Figure 61 shows the recommended decoupling network. This capacitive network performs the following three functions: (1) along with the reference
amplifier, A2, it provides a low source impedance over a large
frequency range to drive the A/D internal circuitry, (2) it provides the necessary compensation for A2, and (3) it bandlimits
the noise contribution from the reference. The turn-on time of
the reference voltage appearing between CAPT and CAPB is
approximately 15 ms and should be evaluated in any powerdown mode of operation.
–24–
REV. B
AD9260
AD9260
VREF
0.1F
+
10F
CAPT
SENSE
REFCOM
state. Table VI indicates the relationship between the CS and
READ pins and the state of Pins Bit 1–Bit 16.
0.1F
0.1F
+
Table VI. CS and READ Pin Functionality
10F
CAPB
0.1F
Figure 61. Recommended Reference Decoupling Network
DIGITAL INPUTS AND OUTPUTS
Digital Outputs
The AD9260 output data is presented in a twos complement
format. Table V indicates the output data formats for various
input ranges and decimation modes. A straight binary output
data format can be created by inverting the MSB.
Condition (V)
1000 0000 0000 0000
1000 0000 0000 0000
0000 0000 0000 0000
0111 1111 1111 1111
0111 1111 1111 1111
4 Decimation Mode
VINA–VINB < –0.825 × VREF
VINA–VINB = –0.825 × VREF
VINA–VINB = 0
VINA–VINB = +0.825 × VREF – 1 LSB
VINA–VINB >= + 0.825 × VREF
1000 0001 0001 1100
1000 0001 0000 1100
0000 0000 0000 0000
0111 1110 1110 0011
0111 1110 1110 0011
2 Decimation Mode
VINA–VINB < –0.825 × VREF
VINA–VINB = –0.825 × VREF
VINA–VINB = 0
VINA–VINB = +0.825 × VREF – 1 LSB
VINA–VINB >= + 0.825 × VREF
Low
Low
High
High
Low
High
Low
High
Data Output Pins in Hi-Z State
ADC Data on Output Pins
Data Output Pins in Hi-Z State
Data Output Pins in Hi-Z State
RESET PIN
The RESET pin is an asynchronous digital input that is active
low. Upon asserting RESET low, the clocks in the digital decimation filters are disabled, the DAV pin goes low and the data
on the digital output data pins (Bit 1–Bit 16) is invalid. In addition, the analog modulator in the AD9260 and internal clock
dividers used in the decimation filters are reset and will remain
reset as long as RESET is maintained low. In the 2×, 4×, or 8×
mode, the RESET must remain low for at least a clock period to
ensure all the clock dividers and analog modulator are reset.
Upon bringing RESET high, the internal clock dividers will
begin to count again on the next falling edge of CLK and DAV
will go high approximately 15 ns after this falling edge, resuming
normal operation. Refer to Figure 4b for a timing diagram.
1000 0000 0100 0001
1000 0000 0100 0001
0000 0000 0000 0000
0111 1111 1011 1110
0111 1111 1011 1110
The slight different ± full-scale input voltage conditions and
their corresponding digital output code for the 4× and 2× decimation modes can be attributed to the different digital scaling
factors applied to each of the AD9260’s FIR decimation stages
for filter optimization purposes. Thus, a + full-scale reading of
0111 1111 1111 1111 and – full-scale reading of 1000 0000
0000 0000 is unachievable in the 2× and 4× decimation mode.
As a result, a digital overrange condition can never exist in the
2× and 4× decimation mode and thus OTR being set high indicates an overrange condition in the analog modulator.
The output data format in 1× decimation differs from that in 2×,
4× and 8× decimation modes. In 1× decimation mode the output data remains in a twos complement format, but the digital
numbers are scaled by a factor of 7/128. This factor of 7/128 is
the product of an internal scale factor of 7/8 in the analog modulator and a 1/16 scale factor caused by LSB justification of the
12-bit modulator data.
CS AND READ PINS
The CS and READ pins control the state of the output data
pins (BIT1–BIT16) on the AD9260. The CS pin is active low
and the READ pin is active high. When CS and READ are
both active the ADC data is driven on the output data pins,
otherwise the output data pins are in a high-impedance (Hi-Z)
REV. B
Condition of Data Output Pins
The DAV pin indicates when the output data of the AD9260 is
valid. Digital output data is updated on the rising edge of DAV.
The data hold time (tH) is dependent on the external loading of
DAV and the digital data output pins (BIT1–BIT16) as well as
the particular decimation mode. The internal DAV driver is
sized to be larger than the drivers pertaining to the digital data
outputs to ensure that rising edge of DAV occurs before the
data transitions under similar loading conditions (i.e., fanout)
regardless of mode. Note that minimum data hold (tH) of 3.5 ns
is specified in the Figure 4 timing diagram from the 50% point
of DAV’s rising edge to the 50% of data transition using a capacitive load of 20 pF for DAV and BIT1–BIT16. Applications
interfacing to TTL logic and/or having larger capacitive loading
for DAV than BIT1–BIT16 should consider latching data on
the falling edge of DAV since the falling edge of DAV occurs
well after the data has transitioned in the case of the 2×, 4× and
8× modes. The duty cycle of DAV is approximately 50% and it
remains active independent of CS and READ.
Digital Output
8 Decimation Mode
VINA–VINB < –0.8 × VREF
VINA–VINB = –0.8 × VREF
VINA–VINB = 0
VINA–VINB = +0.8 × VREF – 1 LSB
VINA–VINB >= + 0.8 × VREF
READ
DAV PIN
Table V. Output Data Format
Input (V)
CS
The state of the internal decimation filters in the AD9260
remains unchanged when RESET is asserted low. Consequently, when RESET is pulsed low, this resets the analog
modulator but does not clear all the data in the digital filters.
The data in the filters is corrupted by the effect of resetting the
analog modulator (this causes an abrupt change at the input of
the digital filter and this change is unrelated to the signal at the
input of the A/D converter). Similarly, in multiplexed applications in which the input of the A/D converters sees an abrupt
change, the data in the analog modulator and digital filter will
be corrupted.
For this reason, following a pulse on the RESET pin, or change
in channels (i.e., multiplexed applications only), the decimation
filters must be flushed of their data. These filters have a memory
length, hence delay, equal to the number of filter taps times
the clock rate of the converter. This memory length may be
–25–
AD9260
interpreted in terms of a number of samples stored in the
decimation filter. For example, if the part is in 8× decimation
mode, the delay is 321/fCLOCK. This corresponds to 321 samples
stored in the decimation filter. These 321 samples must be
flushed from the AD9260 after RESET is pulsed high prior to
reusing the data from the AD9260. That is, the AD9260 should
be allowed to clock for 321 samples as the corrupted data is
flushed from the filters. If the part is in 4× or 2× decimation
mode, then the relatively smaller group delays of the 4× and 2×
decimation filters result fewer samples that must be flushed
from the filters (108 samples and 23 samples respectively).
In 2×, 4× or 8× mode, RESET may be used to synchronize
multiple AD9260s clocked with the same clock. The decimation
filters in the AD9260 are clocked with an internal clock divider.
The state of this clock divider determines when the output data
becomes available (relative to CLK). In order to synchronize
multiple AD9260s clocked with the same clock, it is necessary
that the clock dividers in each of the individual AD9260s are
all reset to the same state. When RESET is asserted low, these
clock dividers are cleared. On the next falling edge of CLK following the rising edge of RESET, the clock dividers begin counting
and the clock is applied to the digital decimation filters.
OTR PIN
The second out-of-range detector is placed at the output of the
stage three decimation filter and detects whether the low pass
filtered data has exceeded full scale. When this occurs, the filter
output data is hard limited to full scale. The OTR signal is a
logical OR function of the signals from these two internal outof-range detectors. If either of these detectors produces an outof-range signal, the OTR pin goes high and the data may be
seriously corrupted.
If the AD9260 is used in a system that incorporates automatic
gain control (AGC), the OTR signal may be used to indicate
that the signal amplitude should be reduced. This may be particularly effective for use in maximizing the signal dynamic
range if the signal includes high-frequency components that
occasionally exceed full scale by a small amount. If, on the other
hand, the signal includes large amplitude low frequency components that cause the digital filters to overrange, this may cause
the low pass digital filter to overrange. In this case the data may
become seriously corrupted and the digital filters may need to
be flushed. See the RESET pin function description above for
an explanation of the requirements for flushing the digital filters.
OTR should be sampled with the falling edge of CLK. This
signal is invalid while CLK is HIGH.
MODE OPERATION
The OTR pin is a synchronous output that is updated each
CLK period. It indicates that an overrange condition has occurred within the AD9260. Ideally, OTR should be latched on
the falling edge of CLK to ensure proper setup-and-hold time.
However, since an overrange condition typically extends well
beyond one clock cycle (i.e., does not toggle at the CLK rate).
OTR typically remains high for more than a clock cycle, allowing it to be successfully detected on the rising edge of CLK or
monitored asynchronously.
The Mode Select Pin (MODE) allows the user to select one of
four available digital filter modes using a single pin. Each mode
configures the internal decimation filter to decimate at: 1×, 2×,
4× or 8×. Refer to Table VII for mode pin ranges.
The mode selection is performed by using a set of internal comparators, as illustrated in Figure 62, so that each mode corresponds to a voltage range on the input of the MODE pin. The
output of the comparators are fed into encoding logic where, on
the falling edge of the clock, the encoded data is latched.
An overrange condition must be carefully handled because of
the group delays in the low-pass digital decimation filters in the
output stages of the AD9260. When the input signal exceeds
the full-scale range of the converter, this can have a variety of
effects upon the operation of the AD9260, depending on the
duration and amplitude of this overrange condition. A short
duration overrange condition (<< filter group delay) may cause
the analog modulator to briefly overrange without causing the
data in the low pass digital filters to exceed full scale. The analog modulator is actually capable of processing signals slightly
(3%) beyond the full-scale range of the AD9260 without internally clipping. A long duration overrange condition will cause
the digital filter data to exceed full scale. For this reason, the
OTR signal is generated using two separate internal out-ofrange detectors.
Table VII. Recommended Mode Pin Ranges and Configurations
Mode Pin
Range
Typical
Mode Pin
Decimation
Mode
0 V–0.5 V
0.5 V–1.5 V
1.5 V–3.0 V
3.0 V–5.0 V
GND
VREF/2
CML
AVDD
8×
2×
4×
1×
BIAS PIN OPERATION
The first of these out-of-range detectors is placed at the output
of the analog modulator and indicates whether the modulator
output signal has extended 3% beyond the full-scale range of
the converter. If the modulator output signal exceeds 3% beyond full scale, the digital data is hard-limited (i.e., clipped) to a
number that is 3% larger than full scale. Due to the delay of the
switched capacitor analog modulator, the OTR signal is delayed
3 1/2 clock cycles relative to the clock edge in which the overranged analog input signal was sampled.
The Bias Select Pin (BIAS) gives the user, who is able to operate the AD9260 at a slower clock rate, the added flexibility of
running the device in a lower, power consumption mode when it
is clocked at less than 20 MHz.
This is accomplished by scaling the bias current of the AD9260
as illustrated in Figure 63. The bias amplifier drives a source
follower and forces 1 V across REXT, which sets the bias current.
This effectively adjusts the bias current in the modulator amplifiers and FLASH preamplifiers. When a large value of REXT is
used, a smaller bias current is available to the internal amplifier
circuitry. As a result these amplifiers need more time to settle,
thus dictating the use of a slower clock as the power is reduced.
Refer to the characterization curves shown in Figures 41–48
revealing the performance tradeoffs.
–26–
REV. B
AD9260
The scaling is accomplished by properly attaching an external
resistor to the BIAS pin of the AD9260 as shown in Table IX.
REXT is normally 2 kΩ for a clock speed of 20 MHz and scales
inversely with clock rate. Because BIAS is an external pin, minimization of capacitance to this pin is recommended in order to
prevent instability of the bias pin amplifier.
130
FULL BIAS-2k
IAVDD – mA
110
AVDD
90
HALF BIAS-4k
70
4R
50
QUARTER BIAS-8k
3R
MODE PIN
2R
ENCODER
30
5
LATCH
ENCODED MODE
10
15
SAMPLE RATE – MSPS
20
Figure 64. IAVDD vs. Sample Rate (AVDD = +5 V,
Mode 1 ×–4 ×)
16
CLOCK
4
8
14
R
12
IDVDD/IDRVDD – mA
AVSS
Figure 62. Simplified Mode Pin Circuitry
BIAS CURRENT
1
10
2
8
6
4
1V
2
0
5
BIAS PIN
10
15
SAMPLE RATE – MSPS
Figure 65a. IDVDD/IDRVDD vs. Sample Rate (DVDD = DRVDD =
3 V, fIN = 1 MHz)
REXT
Figure 63. Simplified Bias Pin Circuitry
30
8
4
POWER DISSIPATION CONSIDERATIONS
25
IDVDD/IDRVDD – mA
The power dissipation of the AD9260 is dependent on its
application-specific configuration and operating conditions.
The analog power dissipation as shown in Figure 64 is primarily
a function of its power bias setting and sample rate. It remains
insensitive to the particular input waveform being digitized or
digital filter MODE setting. The digital power dissipation is
primarily a function of the digital supply setting (i.e., +3 V to
+5 V), the sample rate and, to a lesser extent, the MODE setting
and input waveform. Figures 65a and 65b show the total current
dissipation of the “combined” digital (DVDD) and digital driver
supply (DRVDD) for +3 V and +5 V supplies. Note, DVDD
and DRVDD are typically derived from the same supply bus
since no degradation in performance results. A 1 MHz fullscale sine wave was used to ensure maximum digital activity in
the digital filters and the digital drivers had a fanout of one.
Note also that a twofold decrease in digital supply current results when the digital supply is reduced form +5 V to +3 V.
REV. B
20
20
1
15
2
10
5
0
5
10
15
SAMPLE RATE – MSPS
20
Figure 65b. IDVDD/IDRVDD vs. Sample Rate (DVDD = DRVDD
= 5 V, fIN = 1 MHz)
–27–
AD9260
Digital Output Driver Considerations (DRVDD)
The AD9260 output drivers can be configured to interface with
+5 V or 3.3 V logic families by setting DRVDD to +5 V or 3.3 V
respectively. The AD9260 output drivers in each mode are
appropriately sized to provide sufficient output current to drive
a wide variety of logic families. However, large drive currents
tend to cause glitches on the supplies and may affect SINAD
performance. Applications requiring the AD9260 to drive large
capacitive loads or large fanout may require additional decoupling capacitors on DRVDD. The addition of external buffers or
latches helps reduce output loading while providing effective
isolation from the databus.
Clock Input and Considerations
The AD9260 internal timing uses the two edges of the clock
input to generate a variety of internal timing signals. The clock
input must meet or exceed the minimum specified pulse width
high and low (tCH and tCL) specifications for the given A/D as
defined in the Switching Specifications at the beginning of the
data sheet to meet the rated performance specifications. For
example, the clock input to the AD9260 operating at 20 MSPS
may have a duty cycle between 45% to 55% to meet this timing
requirement since the minimum specified tCH and tCL is 22.5 ns.
For clock rates below 20 MSPS, the duty cycle may deviate from
this range to the extent that both tCH and tCL are satisfied.
These characteristics result in both a reduction of electromagnetic interference (EMI) and an overall improvement in
performance.
It is important to design a layout that prevents noise from coupling
onto the input signal. Digital signals should not be run in parallel
with input signal traces and should be routed away from the
input circuitry. While the AD9260 features separate analog and
digital ground pins, it should be treated as an analog component.
The AVSS, DVSS and DRVSS pins must be joined together directly
under the AD9260. A solid ground plane under the A/D is acceptable if the power and ground return currents are managed carefully. Alternatively, the ground plane under the A/D
may contain serrations to steer currents in predictable directions
where cross-coupling between analog and digital would otherwise be unavoidable. The AD9260/EB ground layout, shown in
Figure 76, depicts the serrated type of arrangement. The analog
and digital grounds are connected by a jumper below the A/D.
Analog and Digital Supply Decoupling
The AD9260 features separate analog, digital, and driver supply
and ground pins, helping to minimize digital corruption of sensitive analog signals.
Figure 66 shows the power supply rejection ratio vs. frequency
for a 200 mV p-p ripple applied to AVDD, DVDD, and DAVDD.
All high-speed high-resolution A/Ds are sensitive to the quality of
the clock input. The degradation in SNR at a given full-scale
input frequency (fIN) due to only aperture jitter (tA) can be calculated with the following equation:
90
85
DVDD & DRVDD
80
SNR = 20 log10 [1/(2 π fIN tA)]
75
PSRR – dBFS
In the equation, the rms aperture jitter, tA, represents the rootsum square of all the jitter sources which include the clock input,
analog input signal, and A/D aperture jitter specification. For
example, if a 500 kHz full-scale sine wave is sampled by an A/D
with a total rms jitter of 15 ps, the SNR performance of the A/D
will be limited to 86.5 dB.
70
65
60
55
AVDD
50
The clock input should be treated as an analog signal in cases
where aperture jitter may affect the dynamic range of the
AD9260. In fact, the CLK input buffer is internally powered
from the AD9260’s analog supply, AVDD. Thus the CLK logic
high and low input voltage levels are +3.5 V and +1.0 V, respectively. Supplies for clock drivers should be separated from the
A/D output driver supplies to avoid modulating the clock signal
with digital noise. Low jitter crystal controlled oscillators make
the best clock sources. If the clock is generated from another type
of source (by gating, dividing, or other method), it should be
retimed by the original clock at the last step.
45
40
1
10
100
FREQUENCY – kHz
1000
10000
Figure 66. AD9260 PSRR vs. Frequency (8 × Mode)
In general, AVDD, the analog supply, should be decoupled to
AVSS, the analog common, as close to the chip as physically
possible. Figure 67 shows the recommended decoupling for the
analog supplies; 0.1 µF ceramic chip capacitors should provide
adequately low impedance over a wide frequency range. Note
that the AVDD and AVSS pins are co-located on the AD9260
GROUNDING AND DECOUPLING
Analog and Digital Grounding
Proper grounding is essential in any high-speed, high-resolution
system. Multilayer printed circuit boards (PCBs) are recommended to provide optimal grounding and power schemes. The
use of ground and power planes offers distinct advantages:
4 AVDD
AVDD 44
3 AVSS
AVSS 38
0.1F
0.1F
AD9260
28 AVDD
1. The minimization of the loop area encompassed by a signal
and its return path.
0.1F
29 AVSS
2. The minimization of the impedance associated with ground
and power paths.
3. The inherent distributed capacitor formed by the power plane,
PCB insulation, and ground plane.
–28–
Figure 67. Analog Supply Decoupling
REV. B
AD9260
to simplify the layout of the decoupling capacitors and provide
the shortest possible PCB trace lengths. The AD9260/EB power
plane layout, shown in Figure 77 depicts a typical arrangement
using a multilayer PCB.
The digital activity on the AD9260 chip falls into two general
categories: digital logic, and output drivers. The internal digital
logic draws surges of current, mainly during the clock transitions. The output drivers draw large current impulses while the
output bits are changing. The size and duration of these currents are a function of the load on the output bits: large capacitive loads are to be avoided. Note that the digital logic of the
AD9260 is referenced DVDD while the output drivers are referenced to DRVDD. Also note that the SNR performance of the
AD9260 remains independent of the digital or driver supply
setting.
Speed Design Techniques seminar book, which is available at
www.analog.com/support/frames/lin_frameset.hml.
INSERT 5/3 VOLT LINEAR REGULATOR
FOR 3 OR 3.3V DIGITAL OPERATION
FERRITE
BEAD CORE*
VA
10F
3 DVDD
DVSS
DRVSS
0.1F
VD
AVDD
0.1F
AVSS
BITS 1–16,
DAV
BUFFER
LATCH
AVDD
0.1F
AVSS
CLK
AVDD
0.1F
AVSS
DRVDD 6
AD9260
1 DVSS
DRVDD
AD9260
The decoupling shown in Figure 68, a 0.1 µF ceramic chip
capacitor, is appropriate for a reasonable capacitive load on the
digital outputs (typically 20 pF on each pin). Applications
involving greater digital loads should consider increasing the
digital decoupling proportionally, and/or using external buffers/
latches.
0.1F
DVDD
0.1F
SAMPLING CLOCK
GENERATOR
0.1F
DRVSS 5
Figure 69.
Figure 68. Digital Supply Decoupling
A complete decoupling scheme will also include large tantalum
or electrolytic capacitors on the PCB to reduce low-frequency
ripple to negligible levels. Refer to the AD9260/EB schematic
and layouts in Figures 73–77 for more information regarding the
placement of decoupling capacitors.
An alternative layout and decoupling scheme is shown in Figure
69. This layout and decoupling scheme is well suited for applications in which multiple AD9260s are located on the same PC
board and/or the AD9260 is part of a multicard mixed signal
system in which grounds are tied back at the system supplies
(i.e., star ground configuration). In this case, the AD9260 is
treated as an analog component in which its analog (i.e.,
AVDD) and digital (DVDD and DRVDD) supplies are derived
from the systems +5 V analog supply and all of the AD9260’s
ground pins are tied directly to the analog ground plane which
resides directly underneath the IC.
Referring to Figure 69, each supply pin is directly decoupled to
their respective ground pin or analog ground plane via a ceramic
0.1 µF chip capacitor. Surface mount ferrite beads are used to
isolate the analog (AVDD), digital (DVDD), and driver supplies
(DRVDD) of the AD9260 from the +5 V power buss. Properly
selected ferrite beads can provide more than 40 dB of isolation
from high-frequency switching transients originating from AD9260
supply pins. Further noise immunity from noise is provided by
the inherent power-supply rejection of the AD9260 as shown in
Figure 64. If digital operation at 3 V is desirable for power savings and or to provide for a 3 V digital logic interface, a 5 V to
3 V linear regulator can be used to drive DVDD and/or DRVDD.
A more complete discussion on this layout and decoupling scheme
can be found in Chapter 7, pages 7-27 through 7-55 of the High
REV. B
AD9260 EVALUATION BOARD
GENERAL DESCRIPTION
The AD9260 Evaluation Board is designed to provide an easy
and flexible method of exercising the AD9260 and demonstrate
its performance to data sheet specifications. The evaluation
board is fabricated in four layers: the component layer; the
ground layer; the power layer and the solder layer. The board is
clearly labeled to provide easy identification of components.
Ample space is provided near the analog and clock inputs to
provide additional or alternate signal conditioning.
FEATURES AND USER CONTROL
• Jumper Controlled Mode/OSR Selection: The choice of
Mode/OSR can easily be varied by jumping either JP1,
JP2, JP3 or JP4 as illustrated in Figure 71 within the
Mode/OSR Control Block. To obtain the desired mode
refer to Table VIII.
Table VIII. AD9260 Evaluation Board Mode Select
Mode/OSR
Connect Jumper
1×
2×
4×
8×
JP4
JP2
JP3
JP1
• Selectable Power Bias: The power consumption of the
AD9260 can be scaled down if the user is able to operate the
device at a lower clock frequency. As illustrated in Figure 71,
pin cups are provided for the external resistor (R2) tied to
the BIAS pin of the AD9260. Table IX defines the recommended resistance for a given clock speed to obtain the desired power consumption.
–29–
AD9260
U5
1
NC
2.5/3V
7
2
AD780R
+VIN
NC
6
3
TEMP
VOUT
5
4
GNDS
TRIM
8
1KPOT
VCC2
C18
0.1F
R10
1k
C19
0.1F
AGND
R3
15k
R12
15k
C14
0.1F
VREFEXT
JP10
R11
49.9
AD817R
1V
U6
R4
10k
R13
10k
C17
10F
Q1
2N2222
R9
1k
+
C12
0.1F
C13
10F
R8
390
+
C15
0.1F
AGND
VCC2
AGND
Figure 70. Evaluation Board External Reference Circuitry
Table IX. Evaluation Board Recommended Resistance Value
for External Bias Resistor
Resistor
Value
Clock Speed
(max)
Power
Consumption
2 kΩ
4 kΩ
8 kΩ
16 kΩ
20 MHz
10 MHz
5 MHz
2.5 MHz
585 mW
325 mW
200 mW
150 mW
The external reference circuitry, is illustrated in Figure 70. By
connecting or disconnecting JP10, the external reference can be
configured for either 1.0 V or 2.5 V. That is, by connecting JP10,
the external reference will be configured to provide a 2.5 V
reference. By leaving JP10 open, the external reference will be
configured to provide a 1.0 V reference.
• Data Interfacing Controls: The data interfacing controls
(RESETB, CSB, READ, DAV) are all accessible via SMA
connectors (J2–J5) as illustrated in Figure 71 within the data
interfacing control block. The RESETB, CSB and READ
connections are each supplied with two sets or resistor pin
cups to allow the user to pull-up or pull-down each signal to
a fixed state. R5, R6 and R30 will terminate to ground, while
R7, R28 and R29 terminate to DRVDD. The DAV and
OTR signals are also directly connected to the data output
connector P1. All interfacing controls are buffered through
the CMOS line driver 74HC541.
• Buffered Output Data: The twos complement output data
is buffered through two CMOS noninverting bus transceivers
(U2 and U3) and made available at pin connector P1 as
illustrated in Figure 71 within the data output block.
• Jumper Controlled Reference Source: The choice of
reference for the AD9260 can easily be varied between 1.0 V,
2.5 V or external, by using Jumpers JP5, JP6, JP7 and JP9 as
illustrated in Figure 71 within the reference configuration
block. To obtain the desired reference see Table X.
• Flexible DC or AC Coupled External Clock Inputs: As
illustrated in Figure 71, the AD9260 Evaluation Board is
designed to allow the user the flexibility of selecting how to
connect the external clock source. It is also equipped with a
playpen area for experimenting with optional clock drivers or
crystals.
• Selecting DC or AC Coupled External Clock:
DC Coupled: To directly drive the clock externally via the
CLKIN connector, connect JP11 and disconnect JP12. Note:
50 Ω terminated by R27.
AC Coupled: To ac couple the external clock and level shift it
to midsupply, connect JP12 and disconnect JP11. Note: 50 Ω
terminated by R27.
• Flexible Input Signal Configuration Circuitry: The
AD9260 Evaluation Board’s Input Signal Configuration Block
is illustrated in Figure 72. It is comprised of an input signal
summing amplifier (U7), a variable input signal commonmode generator (U10) and a pair of amplifiers (U8 and U9)
that configure the input into a differential signal and drive it,
through a pair of isolation resistors, into the input pins of
AD9260. The user can either input a signal or dual signal
into the evaluation board via the two SMA connectors (J6 and
J7) labeled IN-1 or IN-2.
The user should refer to the Driving the Input section of the data
sheet for a detailed explanation of how the inputs are to be driven
and what amplifier requirements are recommended.
Table X. Evaluation Board Reference Pin Configuration
Reference
Voltage
Connect Jumper
Input Voltage
(pk-pk FS)
2.5 V
1.0 V
External
JP7
JP6
JP5, JP9 and JP10
4.0 V
1.6 V
4.0 V
• Selecting Single or Dual Signal Input: The input amplifier (U7) can either be configured as a dual input signal
inverting summer or a single tone inverting buffer. This
flexibility will allow for slightly better noise performance in
the single tone mode due to the inherent noise gain difference in the two amplifier configurations. An optional feedback capacitor (C9) was added to allow the user additional
out-of band filtering of the input signal if needed.
–30–
REV. B
AD9260
For two-tone input signals: The user would leave jumpers (JP8)
connected and use IN-1 and IN-2 (J7 and J6) as the connectors for the input signals.
For signal tone input signal: The user would remove jumper
(JP8) and use only IN-1 as the input signal connector.
• Selectable Input Signal Common-Mode Level Source:
The input signal’s common-mode level (CML) can be set by
U10.
To use the Input CML generated by U10: Disconnect jumper
JP13 and Connect resistors RX3 and RX4. The CML generated by U10 is variable and adjustable using the 1 kΩ
trimpot R35.
SHIPMENT CONFIGURATION AND QUICK SETUP
• The AD9260 Evaluation Board is configured as follows when
shipped:
1. 2.5 V external reference/4.0 V differential full-scale input:
JP5, JP9 and JP10 connected, JP6 and JP7 disconnected.
3. Full Speed Power Bias: R2 = 2 kΩ and connected.
4. CSB pulled low: R6 = 49.9 Ω and connected, R29
disconnected.
5. RESETB pulled high: R7 = 10 kΩ and connected, R30 disconnected.
6. READ pulled high: R28 = 10 kΩ and connected, R5
disconnected.
7. Single Tone Input: JP8 removed, input applied via IN-1 (J7).
9. AC Coupled Clock: JP12 connected and JP11 disconnected.
Note: 50 Ω terminated by R27.
QUICK SETUP
1. Connect the required power supplies to the Evaluation
Board as illustrated in Figure 22:
⇒ ± 5 VA supplies to P5—Analog Power
⇒ +5 VA supply to P4—Analog Power
⇒ +5 VD supply to P3—Digital Power
⇒ +5 VD supply to P2—Driver Power
2. Connect a Clock Source to CLKIN (J1): Note: 50 Ω terminated by R1.
3. Connect an Input Signal Source to the IN-1 (J7).
4. Turn On Power!
5. The AD9260 Evaluation Board is now ready for use.
APPLICATION TIPS
1. The ADC analog input should not be overdriven. Using a
signal amplitude slightly lower than FSR will allow a
small amount of “headroom” so that noise or DC offset
voltage will not overrange the ADC and “hard limit” on
signal peaks.
4. Test signal generators must have exceptional noise performance to achieve accurate SNR measurements. Good generators, together with fifth-order elliptical bandpass filters,
are recommended for SNR tests. Narrow bandwidth crystal
filters can also be used to filter generator broadband noise,
but they should be carefully tested for operation at highsignal levels.
5. The analog inputs of the AD9260 should be terminated
directly at the input pin sockets with the correct filter terminating impedance (50 Ω or 75 Ω), or it should be driven by
a low output impedance buffer. Short leads are necessary to
prevent digital noise pickup.
6. A low noise (jitter) clock signal generator is required for
good ADC dynamic performance. A poor generator can
seriously impair good SNR performance particularly at
higher input frequencies. A high-frequency generator, based
on a clock source (e.g., crystal source), is recommended.
Frequency-synthesized clock generators should generally be
avoided because they typically provide poor jitter performance. See Note 8 if a crystal-based clock generator is used
during FFT testing.
2. 8× Mode/OSR: JP1 connected, JP2, JP3, and JP4
disconnected.
8. Input signal common-mode level set by Trimpot R35 to
2.0 V: Jumper JP12 is disconnected and resistors Rx4 and
Rx3 are connected.
3. Bandpass filtering of test signal generators is absolutely
necessary for SNR, THD and IMD tests. Note, a low noise
signal generator along with a high Q bandpass filter is often
necessary to achieve the attainable noise performance of the
AD9260.
A low jitter clock may be generated by using a high-frequency
clock source and dividing this frequency down with a low noise
clock divider to obtain the AD9260 input CLK. Maintaining a
large amplitude clock signal may also be very beneficial in minimizing the effects of noise in the digital gates of the clock generation circuitry.
Finally, special care should be taken to avoid coupling noise
into any digital gates preceding the AD9260 CLK pin. Short
leads are necessary to preserve fast rise times and careful decoupling should be used with these digital gates and the supplies
for these digital gates should be connected to the same supplies
as that of the internal AD9260 clock circuitry (Pins 44 and 38).
7. Two-tone testing will require isolation between test signal
generators to prevent IMD generation in the test generator
output circuits.
8. A very low side-lobe window must be used for FFT calculations if generators cannot be phase-locked and set to exact
frequencies.
9. A well designed, clean PC board layout will assure proper
operation and clean spectral response. Proper grounding
and bypassing, short lead lengths, separation of analog and
digital signals, and the use of ground planes are particularly
important for high-frequency circuits. Multilayer PC boards
are recommended for best performance, but if carefully
designed, a two-sided PC board with large heavy (20 oz.
foil) ground planes can give excellent results.
10. Prototype “plug-boards” or wire-wrap boards will not be
satisfactory.
2. Two-tone tests can produce signal envelopes that exceed
FSR. Set each test signal to slightly less than –6 dB to prevent “hard limiting” on peaks.
REV. B
–31–
1V
CML
JP3:4
JP1:8
JP2:2
C3
0.1F
C1
0.1F
C5
0.1F
TP2
C2
0.1F
AGND
C6
10F
CML
J1
CLKIN
R27
49.9k
R29
10k
C61
10F
AD9260
JP13
AC COUPLED
C62
0.1F
22
21
20
19
18
17
16
15
14
13
12
R5
49.9
READ
J3
BIT03
BIT04
BIT05
BIT06
BIT07
BIT08
BIT09
BIT10
BIT11
BIT12
BIT13
R6
R28
49.9 10k
1 2 3 4 5 6 7 8 9 10 11
JP11
DC COUPLED
R33
1k
R30
49.9
33 32 31 30 29 28 27 26 25 24 23
MODE
BIAS
CAPB
CAPT
AVSS
CML
NC
VINA
VINB
NC
AVDD
CT20
39
40
41
42
43
44
34
35
36
37
38
R31
1k
W2
C8
0.1F
CT19
C7
0.1F
INVDD
VINA
VINB
W1
TP4:REFB
TP5:REFT
C11
0.1F
JP6:1V REF
TP6
DVDD
C4
10F
TP3
C10 +
10F
JP5:EXT REF
R2
2k
VREFEXT
TP7 TP9 TP11 TP12 TP13 TP15
MDAVDD
JP4:1
MODE/OSR
CONTROL BLOCK
JP7:2.5V REF
DVDD
FLAVDD
MDAVDD
RD
R7
10k
J4
OTR
BIT01(MSB)
BIT02
JP9:EXT REF
DRVDD
CS
REFCOM
VREF
SENSE
RESET
AVSS
AVDD
CS
DAV
SHIELDED_TRACE
–32–
DVSS
AVSS
DVDD
AVDD
DRVSS
DRVDD
CLK
READ
BIT16(LSB)
BIT15
BIT14
REFERENCE CONFIGURATION
BLOCK
MDAVDD
RESET
J5
DAV
J2
2
3
4
5
6
7
8
9
U4
VCC
OUT_EN
B1
B2
B3
B4
B5
B6
B7
B8
74HC245
DIR
A1
A2
A3
A4
A5
A6
A7
A8
GND
DRVDD
U3
20
19
18
17
16
15
14
13
12
11
NC = NO CONNECT
1
2
3
4
5
6
7
8
9
10
CT18
20
19
18
17
16
15
14
13
12
11
DRVDD
P1
P1
P1
P1
P1
P1
P1
P1
17
19
21
23
25
27
29
31
1
3
5
7
9
11
13
15
2
4
6
8
10
12
14
16
18
20
22
24
26
28
30
32
34
38
40
TP10
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1 39
P1 37
P1 35
P1 33
P1 38
TP8:OTR
JP15
DATA OUTPUT BLOCK
CT9
CT10
CT11
CT12
CT13
CT14
CT15
CT16
DRVDD
CT1
CT2
CT3
CT4
CT5
CT6
CT7
CT8
P1
P1
P1
P1
P1
P1
P1
P1
TP1:RD
RD
DRVDD
DRVDD
CT17
VCC
OUT_EN
B1
B2
B3
B4
B5
B6
B7
B8
U2
18
17
16
15
14
13
12
11
74HC245
DIR
A1
A2
A3
A4
A5
A6
A7
A8
GND
RESETB
CSBBUE
Y1
Y2
Y3
Y4
Y5
Y6
Y7
Y8
20
VCC 10
GND
74HC541
1
2
3
4
5
6
7
8
9
10
A1
A2
A3
A4
A5
A6
A7
A8
1 G1
19 G2
DATA OUTPUT CONTROL BLOCK
AD9260
Figure 71. Evaluation Board Top Level Schematic
REV. B
AD9260
R18
390
C20
0.1F
VCC2
C9
TBD
R19
390
R21
390
J6
IN-2
JP8
R1
57.6
IN-1
3
VEE
2
5
2
4
6
4
5
C16
100pF
U7
VEE
R20
390
6
AD9632
R15
57.6
U8
7
AD9632
R17
390
R16
390
J7
8
R22
390
7
3
R47
50
R46
50
JP16
VINA
8
R14
50
VCC2
R23
390
C24
100pF
VCC2
8
3
U9
7
R24
390
R48
50
JP17
6
AD9632
VINB
4
2
R49
50
C26
100pF
5
R32
390
VCC2
R34
390
IKPOT
R35
1k
2
RX3
XXX
7
AD817R
3
VEE
R25
390
R26
390
CX4
XXX
U10
RX4
XXX
JP12
6
9260CML
4
C25
0.1F
+
C23
10F
C22
0.1F
Figure 72. Evaluation Board Input Configuration Block
L3
1
P4:+5V
R41
FLAVDD
+
C36
10F
R40
C38
0.1F
P5:+5AUX
P5
R43
P5:–5AUX
R50
C27
47F
C55
0.1F
2
L7
1
+
C40
10F
+
C42
0.1F
C43
0.01F
C41
0.1F
L5
P5
P2:VDD
R45
+
P4
P3:D5
2
L2
1
2
R44
C46
0.1F
L2
R37
DRVDD
R36
C28
47F
C29
0.1F
2
VEE
R39
C57
0.1F
+
P2
C56
47F
1
C47
0.01F
C45
0.1F
VEE
VCC2
VEE
VCC2
C32
22F
R38
C34
0.1F
C30
0.1F
C35
0.01F
C33
0.1F
EVALUATION BOARD POWER SUPPLY CONFIGURATION
C31
0.1F
C48
0.1F
C64
0.1F
U7
U8
U9
U7
VCC2
DRVDD
DRVDD
DRVDD
C51
0.1F
U10
C52
0.1F
U2
C53
0.1F
U3
C49
0.1F
U8
C54
0.1F
U4
DEVICE SUPPLY DECOUPLING
Figure 73. Evaluation Board Power Supply Configuration and Coupling
REV. B
VCC2
DVDD
+
P3
C44
10F
R52
2
INVDD
R53
VEE
MDAVDD
R42
R51
VCC2
+
C39
0.01F
C37
0.1F
L4
L6
1
–33–
C50
0.1F
U9
AD9260
Figure 74. Evaluation Board Component Side Layout (Not to Scale)
Figure 75. Evaluation Board Solder Side Layout (Not to Scale)
–34–
REV. B
AD9260
Figure 76. Evaluation Board Ground Plane Layout (Not to Scale)
Figure 77. Evaluation Board Power Plane Layout (Not to Scale)
REV. B
–35–
AD9260
OUTLINE DIMENSIONS
Dimensions shown in millimeters and (inches).
44-Lead MQFP
(S-44)
1.03 (0.041)
0.73 (0.029)
C3197a–0–5/00 (rev. B) 00581
13.45 (0.529)
12.95 (0.510)
2.45 (0.096)
MAX
10.1 (0.398)
9.90 (0.390)
0°
MIN
44
34
1
33
SEATING
PLANE
8.45 (0.333)
8.3 (0.327)
TOP VIEW
(PINS DOWN)
11
0.25 (0.01)
MIN
0.23 (0.009)
0.13 (0.005)
23
12
0.8 (0.031)
BSC
0.45 (0.018)
0.3 (0.012)
PRINTED IN U.S.A.
2.1 (0.083)
1.95 (0.077)
22
–36–
REV. B