AD AD7949BCPZRL7

14-Bit, 8-Channel,
250 kSPS PulSAR ADC
AD7949
FEATURES
APPLICATIONS
Multichannel system monitoring
Battery-powered equipment
Medical instruments: ECG/EKG
Mobile communications: GPS
Power line monitoring
Data acquisition
Seismic data acquisition systems
Instrumentation
Process control
FUNCTIONAL BLOCK DIAGRAM
0.5V TO VDD – 0.5V
0.1µF
2.3V TO 5.5V
0.5V TO VDD
10µF
REFIN
REF
BAND GAP
REF
VDD
1.8V
VIO TO
VDD
AD7949
TEMP
SENSOR
IN0
IN1
IN2
IN3
IN4
IN5
IN6
IN7
CNV
14-BIT SAR
ADC
MUX
SPI SERIAL
INTERFACE
ONE-POLE
LPF
SCK
SDO
DIN
SEQUENCER
COM
07351-001
14-bit resolution with no missing codes
8-channel multiplexer with choice of inputs
Unipolar single-ended
Differential (GND sense)
Pseudobipolar
Throughput: 250 kSPS
INL/DNL: ±0.5/±0.25 LSB typical
SINAD: 85 dB @ 20 kHz
THD: −100 dB @ 20 kHz
Analog input range: 0 V to VREF with VREF up to VDD
Multiple reference types
Internal selectable 2.5 V or 4.096 V
External buffered (up to 4.096 V)
External (up to VDD)
Internal temperature sensor (TEMP)
Channel sequencer, selectable 1-pole filter, busy indicator
No pipeline delay, SAR architecture
Single-supply 2.3 V to 5.5 V operation with
1.8 V to 5.5 V logic interface
Serial interface compatible with SPI, MICROWIRE,
QSPI, and DSP
Power dissipation
2.9 mW @ 2.5 V/200 kSPS
10.8 mW @ 5 V/250 kSPS
Standby current: 50 nA
20-lead 4 mm × 4 mm LFCSP package
GND
Figure 1.
Table 1. Multichannel 14-/16-Bit PulSAR® ADCs
Type
14-Bit
16-Bit
16-Bit
Channels
8
4
8
250 kSPS
AD7949
AD7682
AD7689
500 kSPS
AD7699
ADC Driver
ADA4841-x
ADA4841-x
ADA4841-x
GENERAL DESCRIPTION
The AD7949 is an 8-channel, 14-bit, charge redistribution
successive approximation register (SAR) analog-to-digital
converter (ADC) that operates from a single power supply, VDD.
The AD7949 contains all components for use in a multichannel,
low power data acquisition system, including a true 14-bit SAR
ADC with no missing codes; an 8-channel, low crosstalk
multiplexer that is useful for configuring the inputs as singleended (with or without ground sense), differential, or bipolar;
an internal low drift reference (selectable 2.5 V or 4.096 V) and
buffer; a temperature sensor; a selectable one-pole filter; and a
sequencer that is useful when channels are continuously
scanned in order.
The AD7949 uses a simple SPI interface for writing to the
configuration register and receiving conversion results. The SPI
interface uses a separate supply, VIO, which is set to the host
logic level. Power dissipation scales with throughput.
The AD7949 is housed in a tiny 20-lead LFCSP with operation
specified from −40°C to +85°C.
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 that may result from its use. Specifications subject to change without notice. No
license is granted by implication or otherwise under any patent or patent rights of Analog Devices.
Trademarks and registered trademarks are the property of their respective owners.
One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 781.329.4700
www.analog.com
Fax: 781.461.3113 ©2008–2009 Analog Devices, Inc. All rights reserved.
AD7949
TABLE OF CONTENTS
Features .............................................................................................. 1 Voltage Reference Output/Input .............................................. 18 Applications ....................................................................................... 1 Power Supply............................................................................... 20 Functional Block Diagram .............................................................. 1 Supplying the ADC from the Reference.................................. 20 General Description ......................................................................... 1 Digital Interface .............................................................................. 21 Revision History ............................................................................... 2 Reading/Writing During Conversion, Fast Hosts.................. 21 Specifications..................................................................................... 3 Reading/Writing After Conversion, Any Speed Hosts.......... 21 Timing Specifications .................................................................. 5 Reading/Writing Spanning Conversion, Any Speed Host .... 21 Absolute Maximum Ratings............................................................ 7 Configuration Register, CFG .................................................... 21 ESD Caution .................................................................................. 7 General Timing Without a Busy Indicator ............................. 23 Pin Configuration and Function Descriptions ............................. 8 General Timing with a Busy Indicator .................................... 24 Typical Performance Characteristics ............................................. 9 Channel Sequencer .................................................................... 25 Terminology .................................................................................... 12 Theory of Operation ...................................................................... 13 Read/Write Spanning Conversion Without a Busy Indicator
....................................................................................................... 26 Overview...................................................................................... 13 Read/Write Spanning Conversion with a Busy Indicator ..... 27 Converter Operation .................................................................. 13 Application Hints ........................................................................... 28 Transfer Functions...................................................................... 14 Layout .......................................................................................... 28 Typical Connection Diagrams .................................................. 15 Evaluating AD7949 Performance............................................. 28 Analog Inputs .............................................................................. 16 Outline Dimensions ....................................................................... 29 Driver Amplifier Choice ............................................................ 18 Ordering Guide .......................................................................... 29 REVISION HISTORY
5/09—Rev. A to Rev. B
Changes to Features Section, Applications Section, and
Figure 1 .............................................................................................. 1
Changes to Specifications Section .................................................. 3
Changes to Timing Specifications Section .................................... 5
Changes to Table 5 ............................................................................ 7
Changes to Figure 4 and Table 6 ..................................................... 8
Changes to Figure 20 ...................................................................... 11
Changes to Converter Operation Section ................................... 13
Changes to Table 7 .......................................................................... 14
Changes to Figure 25 and Figure 26 ............................................. 15
Changes to Bipolar Single Supply Section, Input Structure
Section, and Selectable Low-Pass Filter Section ......................... 16
Changes to Input Configurations Section, Sequencer Section,
and Source Resistance Section ...................................................... 17
Changes to Internal Reference/Temperature Sensor Section ... 18
Added Figure 30; Renumbered Sequentially .............................. 18
Changes to External Reference and Internal Buffer Section,
External Reference Section, and Reference Decoupling
Section .............................................................................................. 19
Added Figure 31 and Figure 32..................................................... 19
Changes to Power Supply Section ................................................ 20
Changed Reading/Writing During Conversion, Fast Hosts
Section to Reading/Writing After Conversion,
Any Speed Hosts ............................................................................. 21
Changes to Configuration Register, CFG Section and
Table 9 .............................................................................................. 22
Added General Timing Without a Busy Indicator Section and
Figure 36 .......................................................................................... 23
Added General Timing with a Busy Indicator Section and
Figure 37 .......................................................................................... 24
Added Channel Sequencer Section, Examples Section, and
Figure 38 .......................................................................................... 25
Changes to Read/Write Spanning Conversion Without a Busy
Indicator Section and Figure 40 ................................................... 26
Changes to Read/Write Spanning Conversion with a Busy
Indicator Section and Figure 42 ................................................... 27
Changes to Evaluating AD7949 Performance Section .............. 28
Added Exposed Pad Notation to Outline Dimensions ............. 29
Changes to Ordering Guide .......................................................... 29
5/08—Rev. 0 to Rev. A
Changes to Ordering Guide .......................................................... 26
5/08—Revision 0: Initial Version
Rev. B | Page 2 of 32
AD7949
SPECIFICATIONS
VDD = 2.3 V to 5.5 V, VIO = 1.8 V to VDD, VREF = VDD, all specifications TMIN to TMAX, unless otherwise noted.
Table 2.
Parameter
RESOLUTION
ANALOG INPUT
Voltage Range
Absolute Input Voltage
Analog Input CMRR
Leakage Current at 25°C
Input Impedance1
THROUGHPUT
Conversion Rate
Full Bandwidth2
¼ Bandwidth2
Transient Response
ACCURACY
No Missing Codes
Integral Linearity Error
Differential Linearity Error
Transition Noise
Gain Error4
Gain Error Match
Gain Error Temperature Drift
Offset Error4
Offset Error Match
Offset Error Temperature Drift
Power Supply Sensitivity
AC ACCURACY5
Dynamic Range
Signal-to-Noise
SINAD
Total Harmonic Distortion
Spurious-Free Dynamic Range
Channel-to-Channel Crosstalk
SAMPLING DYNAMICS
−3 dB Input Bandwidth
Aperture Delay
Conditions/Comments
Min
14
Unipolar mode
Bipolar mode
Positive input, unipolar and bipolar modes
Negative or COM input, unipolar mode
Negative or COM input, bipolar mode
fIN = 250 kHz
Acquisition phase
0
−VREF/2
−0.1
−0.1
VREF/2 − 0.1
VDD = 4.5 V to 5.5 V
VDD = 2.3 V to 4.5 V
VDD = 4.5 V to 5.5 V
VDD = 2.3 V to 4.5 V
Full-scale step, full bandwidth
Full-scale step, ¼ bandwidth
0
0
0
0
14
−1
−1
Typ
VREF/2
68
1
Max
Unit
Bits
+VREF
+VREF/2
VREF + 0.1
+0.1
VREF/2 + 0.1
V
V
dB
nA
250
200
62.5
50
1.8
14.5
Bits
LSB3
LSB
LSB
LSB
LSB
ppm/°C
LSB
LSB
ppm/°C
LSB
VDD = 5 V  5%
±0.5
±0.25
0.1
±0.5
±0.2
±1
±0.5
±0.2
±1
±0.2
fIN = 20 kHz, VREF = 5 V
fIN = 20 kHz, VREF = 4.096 V internal REF
fIN = 20 kHz, VREF = 2.5 V internal REF
fIN = 20 kHz, VREF = 5 V
fIN = 20 kHz, VREF = 5 V, −60 dB input
fIN = 20 kHz, VREF = 4.096 V internal REF
fIN = 20 kHz, VREF = 2.5 V internal REF
fIN = 20 kHz
fIN = 20 kHz
fIN = 100 kHz on adjacent channel(s)
85.6
85.5
85
84
85
33.5
85
84
−100
108
−125
dB6
dB
dB
dB
dB
dB
dB
dB
dB
dB
dB
1.7
0.425
2.5
MHz
MHz
ns
REF = VDD = 5 V
−5
−1
−1
Full bandwidth
¼ bandwidth
VDD = 5 V
Rev. B | Page 3 of 32
84.5
84
+1
+1
kSPS
kSPS
kSPS
kSPS
μs
μs
+5
+1
+1
AD7949
Parameter
INTERNAL REFERENCE
REF Output Voltage
REFIN Output Voltage7
REF Output Current
Temperature Drift
Line Regulation
Long-Term Drift
Turn-On Settling Time
EXTERNAL REFERENCE
Voltage Range
Current Drain
TEMPERATURE SENSOR
Output Voltage8
Temperature Sensitivity
DIGITAL INPUTS
Logic Levels
VIL
VIH
IIL
IIH
DIGITAL OUTPUTS
Data Format9
Pipeline Delay10
VOL
VOH
POWER SUPPLIES
VDD
VIO
Standby Current11, 12
Power Dissipation
Energy per Conversion
TEMPERATURE RANGE13
Specified Performance
Conditions/Comments
Min
Typ
Max
Unit
2.5 V, @ 25°C
4.096 V, @ 25°C
2.5 V, @ 25°C
4.096 V, @ 25°C
2.490
4.086
2.500
4.096
1.2
2.3
±300
±10
±15
50
5
2.510
4.106
V
V
V
V
μA
ppm/°C
ppm/V
ppm
ms
VDD + 0.3
VDD − 0.5
50
V
V
μA
283
1
mV
mV/°C
VDD = 5 V ± 5%
1000 hours
CREF = 10 μF
REF input
REFIN input (buffered)
250 kSPS, REF = 5 V
0.5
0.5
@ 25°C
−0.3
0.7 × VIO
−1
−1
ISINK = +500 μA
ISOURCE = −500 μA
+0.3 × VIO
VIO + 0.3
+1
+1
V
V
μA
μA
0.4
V
V
5.5
VDD + 0.3
VDD + 0.3
V
V
V
nA
μW
mW
mW
mW
mW
VIO − 0.3
Specified performance
Specified performance
Operating range
VDD and VIO = 5 V, @ 25°C
VDD = 2.5 V, 100 SPS throughput
VDD = 2.5 V, 100 kSPS throughput
VDD = 2.5 V, 200 kSPS throughput
VDD = 5 V, 250 kSPS throughput
VDD = 5 V, 250 kSPS throughput with internal
reference
2.3
2.3
1.8
50
1.5
1.45
2.9
10.8
13.5
2.0
4.0
12.5
15.5
50
TMIN to TMAX
−40
1
nJ
+85
°C
See the Analog Inputs section.
The bandwidth is set in the configuration register.
LSB means least significant bit. With the 5 V input range, one LSB = 305 μV.
4
See the Terminology section. These specifications include full temperature range variation but not the error contribution from the external reference.
5
With VDD = 5 V, unless otherwise noted.
6
All specifications expressed in decibels are referred to a full-scale input FSR and tested with an input signal at 0.5 dB below full scale, unless otherwise specified.
7
This is the output from the internal band gap.
8
The output voltage is internal and present on a dedicated multiplexer input.
9
Unipolar mode: serial 14-bit straight binary.
Bipolar mode: serial 14-bit twos complement.
10
Conversion results available immediately after completed conversion.
11
With all digital inputs forced to VIO or GND as required.
12
During acquisition phase.
13
Contact an Analog Devices, Inc., sales representative for the extended temperature range.
2
3
Rev. B | Page 4 of 32
AD7949
TIMING SPECIFICATIONS
VDD = 4.5 V to 5.5 V, VIO = 1.8 V to VDD, all specifications TMIN to TMAX, unless otherwise noted.
Table 3.
Parameter1
Conversion Time: CNV Rising Edge to Data Available
Acquisition Time
Time Between Conversions
Data Write/Read During Conversion
CNV Pulse Width
SCK Period
SCK Low Time
SCK High Time
SCK Falling Edge to Data Remains Valid
SCK Falling Edge to Data Valid Delay
VIO Above 2.7 V
VIO Above 2.3 V
VIO Above 1.8 V
CNV Low to SDO D15 MSB Valid
VIO Above 2.7 V
VIO Above 2.3 V
VIO Above 1.8 V
CNV High or Last SCK Falling Edge to SDO High Impedance
CNV Low to SCK Rising Edge
DIN Valid Setup Time from SCK Rising Edge
DIN Valid Hold Time from SCK Rising Edge
1
Symbol
tCONV
tACQ
tCYC
tDATA
tCNVH
tSCK
tSCKL
tSCKH
tHSDO
tDSDO
Min
Typ
Max
2.2
1.8
4.0
1.0
10
tDSDO + 2
11
11
4
Unit
μs
μs
μs
μs
ns
ns
ns
ns
ns
18
23
28
ns
ns
ns
18
22
25
32
ns
ns
ns
ns
ns
ns
ns
tEN
tDIS
tCLSCK
tSDIN
tHDIN
See Figure 2 and Figure 3 for load conditions.
Rev. B | Page 5 of 32
10
5
5
AD7949
VDD = 2.3 V to 4.5 V, VIO = 1.8 V to VDD, all specifications TMIN to TMAX, unless otherwise noted.
Table 4.
Parameter1
Conversion Time: CNV Rising Edge to Data Available
Acquisition Time
Time Between Conversions
Data Write/Read During Conversion
CNV Pulse Width
SCK Period
SCK Low Time
SCK High Time
SCK Falling Edge to Data Remains Valid
SCK Falling Edge to Data Valid Delay
VIO Above 3 V
VIO Above 2.7 V
VIO Above 2.3 V
VIO Above 1.8 V
CNV Low to SDO D15 MSB Valid
VIO Above 3 V
VIO Above 2.7 V
VIO Above 2.3 V
VIO Above 1.8 V
CNV High or Last SCK Falling Edge to SDO High Impedance
CNV Low to SCK Rising Edge
DIN Valid Setup Time from SCK Rising Edge
DIN Valid Hold Time from SCK Rising Edge
Min
Max
3.2
1.2
10
tDSDO + 2
12
12
5
Unit
μs
μs
μs
μs
ns
ns
ns
ns
ns
24
30
38
48
ns
ns
ns
ns
21
27
35
45
50
ns
ns
ns
ns
ns
ns
ns
ns
tEN
tDIS
tCLSCK
tSDIN
tHDIN
10
5
5
See Figure 2 and Figure 3 for load conditions.
500µA
IOL
1.4V
TO SDO
CL
50pF
500µA
IOH
Figure 2. Load Circuit for Digital Interface Timing
70% VIO
30% VIO
tDELAY
2V OR VIO – 0.5V1
2V OR VIO – 0.5V1
0.8V OR 0.5V2
0.8V OR 0.5V2
2V IF VIO ABOVE 2.5V, VIO – 0.5V IF VIO BELOW 2.5V.
0.8V IF VIO ABOVE 2.5V, 0.5V IF VIO BELOW 2.5V.
Figure 3. Voltage Levels for Timing
Rev. B | Page 6 of 32
07351-003
tDELAY
1
2
Typ
1.8
5
07351-002
1
Symbol
tCONV
tACQ
tCYC
tDATA
tCNVH
tSCK
tSCKL
tSCKH
tHSDO
tDSDO
AD7949
ABSOLUTE MAXIMUM RATINGS
Table 5.
Parameter
Analog Inputs
INx,1 COM1
REF, REFIN
Supply Voltages
VDD, VIO to GND
VIO to VDD
DIN, CNV, SCK to GND
SDO to GND
Storage Temperature Range
Junction Temperature
θJA Thermal Impedance (LFCSP)
θJC Thermal Impedance (LFCSP)
1
Rating
GND − 0.3 V to VDD + 0.3 V
or VDD ± 130 mA
GND − 0.3 V to VDD + 0.3 V
−0.3 V to +7 V
−0.3 V to VDD + 0.3 V
−0.3 V to VIO + 0.3 V
−0.3 V to VIO + 0.3 V
−65°C to +150°C
150°C
47.6°C/W
4.4°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
section of this specification is not implied. Exposure to absolute
maximum rating conditions for extended periods may affect
device reliability.
ESD CAUTION
See the Analog Inputs section.
Rev. B | Page 7 of 32
AD7949
20
19
18
17
16
VDD
IN3
IN2
IN1
IN0
PIN CONFIGURATION AND FUNCTION DESCRIPTIONS
1
2
3
4
5
PIN 1
INDICATOR
AD7949
TOP VIEW
(Not to Scale)
15
14
13
12
11
VIO
SDO
SCK
DIN
CNV
NOTES
1. THE EXPOSED PAD IS NOT CONNECTED
INTERNALLY. FOR INCREASED
RELIABILITY OF THE SOLDER JOINTS, IT
IS RECOMMENDED THAT THE PAD BE
SOLDERED TO THE SYSTEM
GROUND PLANE.
07351-004
IN4 6
IN5 7
IN6 8
IN7 9
COM 10
VDD
REF
REFIN
GND
GND
Figure 4. Pin Configuration
Table 6. Pin Function Descriptions
Pin No.
1, 20
Mnemonic
VDD
Type1
P
2
REF
AI/O
3
REFIN
AI/O
4, 5
6 to 9
10
GND
IN4 to IN7
COM
P
AI
AI
11
CNV
DI
12
DIN
DI
13
SCK
DI
14
SDO
DO
15
VIO
P
16 to 19
21
(EPAD)
IN0 to IN3
Exposed Pad
(EPAD)
AI
NC
Description
Power Supply. Nominally 2.5 V to 5.5 V when using an external reference and decoupled with
10 μF and 100 nF capacitors.
When using the internal reference for 2.5 V output, the minimum should be 3.0 V.
When using the internal reference for 4.096 V output, the minimum should be 4.5 V.
Reference Input/Output. See the Voltage Reference Output/Input section.
When the internal reference is enabled, this pin produces a selectable system reference = 2.5 V or
4.096 V.
When the internal reference is disabled and the buffer is enabled, REF produces a buffered
version of the voltage present on the REFIN pin (4.096 V maximum), useful when using low cost,
low power references.
For improved drift performance, connect a precision reference to REF (0.5 V to VDD).
For any reference method, this pin needs decoupling with an external 10 μF capacitor
connected as close to REF as possible. See the Reference Decoupling section.
Internal Reference Output/Reference Buffer Input. See the Voltage Reference Output/Input
section.
When using the internal reference, the internal unbuffered reference voltage is present and
needs decoupling with a 0.1 μF capacitor.
When using the internal reference buffer, apply a source between 0.5 V and 4.096 V that is
buffered to the REF pin as described above.
Power Supply Ground.
Channel 4 through Channel 7 Analog Inputs.
Common Channel Input. All input channels, IN[7:0], can be referenced to a common-mode
point of 0 V or VREF/2 V.
Convert Input. On the rising edge, CNV initiates the conversion. During conversion, if CNV is
held high, the busy indictor is enabled.
Data Input. This input is used for writing to the 14-bit configuration register. The configuration
register can be written to during and after conversion.
Serial Data Clock Input. This input is used to clock out the data on SDO and clock in data on DIN
in an MSB first fashion.
Serial Data Output. The conversion result is output on this pin, synchronized to SCK. In unipolar
modes, conversion results are straight binary; in bipolar modes, conversion results are twos
complement.
Input/Output Interface Digital Power. Nominally at the same supply as the host interface (1.8 V,
2.5 V, 3 V, or 5 V).
Channel 0 through Channel 3 Analog Inputs.
The exposed pad is not connected internally. For increased reliability of the solder joints, it is
recommended that the pad be soldered to the system ground plane.
1
AI = analog input, AI/O = analog input/output, DI = digital input, DO = digital output, and P = power.
Rev. B | Page 8 of 32
AD7949
TYPICAL PERFORMANCE CHARACTERISTICS
1.0
1.0
0.5
0.5
DNL (LSB)
0
4,096
8,192
12,288
16,384
CODES
–1.0
07351-005
0
259,473
250k
200k
200k
16,384
150k
150k
100k
100k
50k
50k
0
0
1
0
0
0
0
1FFD
1FFE
1FFF
2000
2001
2002
2003
0
0
07351-006
0
1FFC
VREF = VDD = 2.5V
0
0
955
1FFC 1FFD 1FFE 1FFF
2000
693
0
0
0
2001
2002
2003
2004
CODE IN HEX
Figure 6. Histogram of a DC Input at Code Center
07351-009
COUNTS
250k
CODE IN HEX
Figure 9. Histogram of a DC Input at Code Center
0
0
VREF = VDD = 5V
fS= 250kSPS
fIN = 19.9kHz
SNR = 85.3dB
SINAD = 85.2dB
THD = –100dB
SFDR = 103dB
SECOND HARMONIC = –110dB
THIRD HARMONIC = –103dB
–40
–60
VREF = VDD = 2.5V
fs= 200kSPS
fIN = 19.9kHz
SNR = 84.2dB
SINAD = 82.4dB
THD = –84dB
SFDR = 85dB
SECOND HARMONIC = –100dB
THIRD HARMONIC = –85dB
–20
AMPLITUDE (dB of Full-Scale)
–20
–80
–100
–120
–140
–40
–60
–80
–100
–120
–140
–160
0
25
50
75
100
FREQUENCY (kHz)
125
07351-007
AMPLITUDE (dB of Full-Scale)
12,288
300k
VREF = VDD = 5V
261,120
–160
8,192
Figure 8. Differential Nonlinearity vs. Code, VREF = VDD = 5 V
300k
0
4,096
CODES
Figure 5. Integral Nonlinearity vs. Code, VREF = VDD = 5 V
COUNTS
0
07351-008
–0.5
–0.5
–1.0
0
Figure 7. 20 kHz FFT, VREF = VDD = 5 V
–180
0
25
50
75
FREQUENCY (kHz)
Figure 10. 20 kHz FFT, VREF = VDD = 2.5 V
Rev. B | Page 9 of 32
100
07351-010
INL (LSB)
VDD = 2.5 V to 5.5 V, VREF = 2.5 V to 5 V, VIO = 2.3 V to VDD, unless otherwise noted..
90
90
85
85
80
80
SINAD (dB)
75
75
70
70
50
100
150
200
FREQUENCY (kHz)
60
0
50
100
150
200
FREQUENCY (kHz)
Figure 11. SNR vs. Frequency
Figure 14. SINAD vs. Frequency
15.5
88
SNR
SINAD
ENOB
15.0
86
130
–60
125
–65
120
–70
115
–75
14.0
82
SFDR (dB)
14.5
84
ENOB (Bits)
110
–80
SFDR
105
–85
100
–90
95
–95
THD
90
–100
85
–105
80
–110
75
–115
13.5
80
1.5
2.0
2.5
3.0
3.5
4.0
4.5
5.0
70
1.0
07351-012
13.0
78
1.0
5.5
REFERENCE VOLTAGE (V)
1.5
2.0
2.5
3.0
3.5
4.0
4.5
–120
5.5
5.0
REFERENCE VOLTAGE (V)
Figure 12. SNR, SINAD, and ENOB vs. Reference Voltage
Figure 15. SFDR and THD vs. Reference Voltage
90
–90
fIN = 20kHz
fIN = 20kHz
VDD = VREF = 5V
85
–95
VDD = VREF = 2.5V
VDD = VREF = 5V
THD (dB)
80
75
VDD = VREF = 2.5V
–100
70
–105
60
–55
–35
–15
5
25
45
65
TEMPERATURE (°C)
85
105
125
Figure 13. SNR vs. Temperature
–110
–55
–35
–15
5
25
45
65
TEMPERATURE (°C)
Figure 16. THD vs. Temperature
Rev. B | Page 10 of 32
85
105
125
07351-016
65
07351-013
SNR (dB)
SNR, SINAD (dB)
= 5V, –0.5dB
= 5V, –10dB
= 2.5V, –0.5dB
= 2.5V, –10dB
07351-014
65
60
0
VDD = VREF
VDD = VREF
VDD = VREF
VDD = VREF
THD (dB)
65
= 5V, –0.5dB
= 5V, –10dB
= 2.5V, –0.5dB
= 2.5V, –10dB
07351-011
VDD = VREF
VDD = VREF
VDD = VREF
VDD = VREF
07351-015
SNR (dB)
AD7949
AD7949
100
2750
2.5V INTERNAL REF
4.096V INTERNAL REF
INTERNAL BUFFER, TEMP ON
INTERNAL BUFFER, TEMP OFF
EXTERNAL REF, TEMP ON
EXTERNAL REF, TEMP OFF
VIO
VDD CURRENT (µA)
2250
THD (dB)
–80
–90
–100
= 5V, –0.5dB
= 2.5V, –0.5dB
= 2.5V, –10dB
= 5V, –10dB
–120
0
50
100
150
200
FREQUENCY (kHz)
70
60
1500
50
1250
40
1000
30
750
2.5
3.0
3.5
4.0
4.5
20
5.5
5.0
VDD SUPPLY (V)
Figure 17. THD vs. Frequency
Figure 20. Operating Currents vs. Supply
90
89
80
1750
07351-017
VDD = VREF
VDD = VREF
VDD = VREF
VDD = VREF
–110
2000
90
VIO CURRENT (µA)
2500
–70
fS = 200kSPS
07351-020
–60
180
3000
fIN = 20kHz
fS = 200kSPS
160
2750
88
VDD CURRENT (µA)
SNR (dB)
140
2500
VDD = VREF = 5V
86
85
84
VDD = VREF = 2.5V
83
82
VDD = 5V, INTERNAL 4.096V REF
120
2250
100
2000
VDD = 5V, EXTERNAL REF
80
1750
1500
81
80
60
VIO
VDD = 2.5, EXTERNAL REF
VIO CURRENT (µA)
87
40
1250
79
–6
–4
–2
0
INPUT LEVEL (dB)
1000
–55
–15
5
25
45
65
85
105
20
125
TEMPERATURE (°C)
Figure 18. SNR vs. Input Level
Figure 21. Operating Currents vs. Temperature
25
2
VDD = 2.5V, 85°C
20
tDSDO DELAY (ns)
1
0
–2
–55
UNIPOLAR ZERO
UNIPOLAR GAIN
BIPOLAR ZERO
BIPOLAR GAIN
–35
–15
5
15
VDD = 2.5V, 25°C
10
VDD = 5V, 85°C
VDD = 5V, 25°C
5
VDD = 3.3V, 85°C
VDD = 3.3V, 25°C
25
45
65
85
105
TEMPERATURE (°C)
125
0
0
Figure 19. Offset and Gain Errors vs. Temperature
20
40
60
80
SDO CAPACITIVE LOAD (pF)
100
120
Figure 22. tDSDO Delay vs. SDO Capacitance Load and Supply
Rev. B | Page 11 of 32
07351-022
–1
07351-019
OFFSET ERROR AND GAIN ERROR (LSB)
–35
07351-021
–8
07351-018
78
–10
AD7949
TERMINOLOGY
Least Significant Bit (LSB)
The LSB is the smallest increment that can be represented by a
converter. For an analog-to-digital converter with N bits of
resolution, the LSB expressed in volts is
LSB (V) 
VREF
2N
Integral Nonlinearity Error (INL)
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 ½ LSB before the first
code transition. Positive full scale is defined as a level 1½ LSB
beyond the last code transition. The deviation is measured from
the middle of each code to the true straight line (see Figure 24).
Differential Nonlinearity Error (DNL)
In an ideal ADC, code transitions are 1 LSB apart. DNL is the
maximum deviation from this ideal value. It is often specified in
terms of resolution for which no missing codes are guaranteed.
Signal-to-Noise Ratio (SNR)
SNR is the ratio of the rms value of the actual input signal to the
rms sum of all other spectral components below the Nyquist
frequency, excluding harmonics and dc. The value for SNR is
expressed in decibels.
Signal-to-(Noise + Distortion) Ratio (SINAD)
SINAD is the ratio of the rms value of the actual input signal to
the rms sum of all other spectral components below the Nyquist
frequency, including harmonics but excluding dc. The value for
SINAD is expressed in decibels.
Total Harmonic Distortion (THD)
THD is the ratio of the rms sum of the first five harmonic
components to the rms value of a full-scale input signal and is
expressed in decibels.
Spurious-Free Dynamic Range (SFDR)
SFDR is the difference, in decibels, between the rms amplitude
of the input signal and the peak spurious signal.
Offset Error
The first transition should occur at a level ½ LSB above analog
ground. The offset error is the deviation of the actual transition
from that point.
Effective Number of Bits (ENOB)
ENOB is a measurement of the resolution with a sine wave
input. It is related to SINAD by the formula
Gain Error
The last transition (from 111 … 10 to 111 … 11) should occur
for an analog voltage 1½ LSB below the nominal full scale. The
gain error is the deviation in LSB (or percentage of full-scale
range) of the actual level of the last transition from the ideal
level after the offset error is adjusted out. Closely related is the
full-scale error (also in LSB or percentage of full-scale range),
which includes the effects of the offset error.
and is expressed in bits.
Aperture Delay
Aperture delay is the measure of the acquisition performance. It
is the time between the rising edge of the CNV input and the
point at which the input signal is held for a conversion.
Transient Response
Transient response is the time required for the ADC to accurately
acquire its input after a full-scale step function is applied.
Dynamic Range
Dynamic range is the ratio of the rms value of the full scale to
the total rms noise measured with the inputs shorted together.
The value for dynamic range is expressed in decibels.
ENOB = (SINADdB − 1.76)/6.02
Channel-to-Channel Crosstalk
Channel-to-channel crosstalk is a measure of the level of crosstalk
between any two adjacent channels. It is measured by applying a
dc to the channel under test and applying a full-scale, 100 kHz
sine wave signal to the adjacent channel(s). The crosstalk is the
amount of signal that leaks into the test channel and is expressed
in decibels.
Reference Voltage Temperature Coefficient
Reference voltage temperature coefficient is derived from the
typical shift of output voltage at 25°C on a sample of parts at the
maximum and minimum reference output voltage (VREF) measured
at TMIN, T (25°C), and TMAX. It is expressed in ppm/°C as
TCV REF (ppm/C) 
V REF ( Max ) – V REF ( Min)
V REF ( 25C )  (T MAX – T MIN )
 10 6
where:
VREF (Max) = maximum VREF at TMIN, T (25°C), or TMAX.
VREF (Min) = minimum VREF at TMIN, T (25°C), or TMAX.
VREF (25°C) = VREF at 25°C.
TMAX = +85°C.
TMIN = –40°C.
Rev. B | Page 12 of 32
AD7949
THEORY OF OPERATION
INx+
SWITCHES CONTROL
MSB
8,192C
4,096C
LSB
4C
2C
C
SW+
C
BUSY
REF
COMP
GND
8,192C
4,096C
4C
2C
C
CONTROL
LOGIC
OUTPUT CODE
C
MSB
LSB
SW–
07351-023
CNV
INx– OR
COM
Figure 23. ADC Simplified Schematic
OVERVIEW
CONVERTER OPERATION
The AD7949 is an 8-channel, 14-bit, charge redistribution
successive approximation register (SAR) analog-to-digital
converter (ADC). The AD7949 is capable of converting 250,000
samples per second (250 kSPS) and powers down between
conversions. For example, when operating with an external
reference at 1 kSPS, it consumes 15 μW typically, ideal for
battery-powered applications.
The AD7949 is a successive approximation ADC based on a
charge redistribution DAC. Figure 23 shows the simplified
schematic of the ADC. The capacitive DAC consists of two
identical arrays of 14 binary-weighted capacitors, which are
connected to the two comparator inputs.
The AD7949 contains all of the components for use in a
multichannel, low power data acquisition system, including






14-bit SAR ADC with no missing codes
8-channel, low crosstalk multiplexer
Internal low drift reference and buffer
Temperature sensor
Selectable one-pole filter
Channel sequencer
These components are configured through an SPI-compatible,
14-bit register. Conversion results, also SPI compatible, can be
read after or during conversions with the option for reading
back the configuration associated with the conversion.
The AD7949 provides the user with an on-chip track-and-hold
and does not exhibit pipeline delay or latency.
The AD7949 is specified from 2.3 V to 5.5 V and can be
interfaced to any 1.8 V to 5 V digital logic family. The part is
housed in a 20-lead, 4 mm × 4 mm LFCSP that combines space
savings and allows flexible configurations. It is pin-for-pin
compatible with the 16-bit AD7682, AD7689, and AD7699.
During the acquisition phase, terminals of the array tied to the
comparator input are connected to GND via SW+ and SW−.
All independent switches are connected to the analog inputs.
Thus, the capacitor arrays are used as sampling capacitors and
acquire the analog signal on the INx+ and INx− (or COM)
inputs. When the acquisition phase is complete and the CNV
input goes high, a conversion phase is initiated. When the
conversion phase begins, SW+ and SW− are opened first. The
two capacitor arrays are then disconnected from the inputs and
connected to the GND input. Therefore, the differential voltage
between the INx+ and INx− (or COM) inputs captured at the
end of the acquisition phase is applied to the comparator inputs,
causing the comparator to become unbalanced. By switching
each element of the capacitor array between GND and REF, the
comparator input varies by binary-weighted voltage steps
(VREF/2, VREF/4, ... VREF/8,192). The control logic toggles these
switches, starting with the MSB, to bring the comparator back
into a balanced condition. After the completion of this process,
the part returns to the acquisition phase, and the control logic
generates the ADC output code and a busy signal indicator.
Because the AD7949 has an on-board conversion clock, the
serial clock, SCK, is not required for the conversion process.
Rev. B | Page 13 of 32
AD7949
TRANSFER FUNCTIONS
011...111
111...111
011...110
011...101
111...110
111...101
The ideal transfer characteristic for the AD7949 is shown in
Figure 24 and for both unipolar and bipolar ranges with the
internal 4.096 V reference.
100...010
000...010
100...001
000...001
100...000
000...000
–FSR
–FSR + 1LSB
–FSR + 0.5LSB
+FSR – 1LSB
+FSR – 1.5LSB
ANALOG INPUT
07351-024
With the inputs configured for bipolar range (COM = VREF/2 or
paired differentially with INx− = VREF/2), the data outputs are
twos complement.
TWOS
STRAIGHT
COMPLEMENT
BINARY
ADC CODE
With the inputs configured for unipolar range (single-ended,
COM with ground sense, or paired differentially with INx− as
ground sense), the data output is straight binary.
Figure 24. ADC Ideal Transfer Function
Table 7. Output Codes and Ideal Input Voltages
Description
FSR − 1 LSB
Midscale + 1 LSB
Midscale
Midscale − 1 LSB
−FSR + 1 LSB
−FSR
Unipolar Analog Input1
VREF = 4.096 V
4.095750 V
2.048250 V
2.048000 V
2.047750 V
250 μV
0V
Digital Output Code
(Straight Binary Hex)
0x3FFF3
0x2001
0x2000
0x1FFF
0x0001
0x00004
1
With COM or INx− = 0 V or all INx referenced to GND.
With COM or INx− = VREF /2.
3
This is also the code for an overranged analog input ((INx+) − (INx−), or COM, above VREF − GND).
4
This is also the code for an underranged analog input ((INx+) − (INx−), or COM, below GND).
2
Rev. B | Page 14 of 32
Bipolar Analog Input2
VREF = 4.096 V
2.047750 V
250 μV
0V
−250 μV
−2.047750 V
−2.048 V
Digital Output Code
(Twos Complement Hex)
0x1FFF3
0x0001
0x0000
0x3FFF
0x2001
0x20004
AD7949
TYPICAL CONNECTION DIAGRAMS
5V
100nF
100nF
10µF2
V+
REF
REFIN VDD
1.8V TO VDD
100nF
VIO
0V TO VREF
ADA4841-x 3
IN0
V–
V+
DIN
MOSI
SCK
SCK
SDO
MISO
CNV
SS
IN[7:1]
AD7949
0V TO VREF
ADA4841-x 3
V–
0V OR
VREF /2
COM
NOTES
1. INTERNAL REFERENCE SHOWN. SEE VOLTAGE REFERENCE OUTPUT/INPUT SECTION FOR
REFERENCE SELECTION.
2. CREF IS USUALLY A 10µF CERAMIC CAPACITOR (X5R).
3. SEE THE DRIVER AMPLIFIER CHOICE SECTION FOR ADDITIONAL RECOMMENDED AMPLIFIERS.
4. SEE THE DIGITAL INTERFACE SECTION FOR CONFIGURING AND READING CONVERSION DATA.
07351-025
GND
Figure 25. Typical Application Diagram with Multiple Supplies
1.8V TO VDD
+5V
10µF2
100nF
100nF
100nF
V+
REF
REFIN VDD
VIO
ADA4841-x 3
V–
IN0
DIN
MOSI
SCK
SCK
SDO
MISO
CNV
SS
IN[7:1]
V+
AD7949
ADA4841-x 3
V–
VREF /2
COM
GND
NOTES
1. INTERNAL REFERENCE SHOWN. SEE VOLTAGE REFERENCE OUTPUT/INPUT SECTION FOR
REFERENCE SELECTION.
2. CREF IS USUALLY A 10µF CERAMIC CAPACITOR (X5R).
3. SEE THE DRIVER AMPLIFIER CHOICE SECTION FOR ADDITIONAL RECOMMENDED AMPLIFIERS.
4. SEE THE DIGITAL INTERFACE SECTION FOR CONFIGURING AND READING CONVERSION DATA.
Figure 26. Typical Application Diagram Using Bipolar Input
Rev. B | Page 15 of 32
07351-026
VREF p-p
AD7949
Unipolar or Bipolar
70
Figure 25 shows an example of the recommended connection
diagram for the AD7949 when multiple supplies are available.
65
60
Bipolar Single Supply
CMRR (dB)
55
50
45
40
35
30
For this circuit, a rail-to-rail input/output amplifier can be used;
however, the offset voltage vs. input common-mode range should
be noted and taken into consideration (1 LSB = 250 μV with
VREF = 4.096 V). Note that the conversion results are in twos
complement format when using the bipolar input configuration.
Refer to the AN-581 Application Note, Biasing and Decoupling
Op Amps in Single Supply Applications, at www.analog.com for
additional details about using single-supply amplifiers.
ANALOG INPUTS
Input Structure
1
10
100
FREQUENCY (kHz)
1k
10k
07351-028
Figure 26 shows an example of a system with a bipolar input
using single supplies with the internal reference (optional
different VIO supply). This circuit is also useful when the
amplifier/signal conditioning circuit is remotely located with
some common mode present. Note that for any input configuration, the INx inputs are unipolar and are always referenced
to GND (no negative voltages even in bipolar range).
Figure 28. Analog Input CMRR vs. Frequency
During the acquisition phase, the impedance of the analog inputs
can be modeled as a parallel combination of the capacitor, CPIN,
and the network formed by the series connection of RIN and CIN.
CPIN is primarily the pin capacitance. RIN is typically 2.4 kΩ and
is a lumped component composed of serial resistors and the on
resistance of the switches. CIN is typically 27 pF and is mainly
the ADC sampling capacitor.
Selectable Low-Pass Filter
Figure 27 shows an equivalent circuit of the input structure of
the AD7949. The two diodes, D1 and D2, provide ESD protection for the analog inputs, IN[7:0] and COM. Care must be
taken to ensure that the analog input signal does not exceed the
supply rails by more than 0.3 V because this causes the diodes
to become forward biased and to start conducting current.
These diodes can handle a forward-biased current of 130 mA
maximum. For instance, these conditions may eventually occur
when the input buffer supplies are different from VDD. In such
a case, for example, an input buffer with a short circuit, the
current limitation can be used to protect the part.
During the conversion phase, where the switches are opened,
the input impedance is limited to CPIN. While the AD7949 is
acquiring, RIN and CIN make a one-pole, low-pass filter that
reduces undesirable aliasing effects and limits the noise from
the driving circuitry. The low-pass filter can be programmed for
the full bandwidth or ¼ of the bandwidth with CFG[6], as
shown in Table 9. This setting changes RIN to 19 kΩ. Note that the
converter throughput must also be reduced by ¼ when using the
filter. If the maximum throughput is used with the bandwidth
(BW) set to ¼, the converter acquisition time, tACQ, is violated,
resulting in increased THD.
VDD
D1
INx+
OR INx–
OR COM
CIN
D2
07351-027
CPIN
RIN
GND
Figure 27. Equivalent Analog Input Circuit
This analog input structure allows the sampling of the true
differential signal between INx+ and COM or INx+ and INx−.
(COM or INx− = GND ± 0.1 V or VREF ± 0.1 V). By using these
differential inputs, signals common to both inputs are rejected,
as shown in Figure 28.
Rev. B | Page 16 of 32
AD7949
Figure 29 shows the different methods for configuring the analog
inputs with the configuration register, CFG[12:10]. Refer to the
Configuration Register, CFG, section for more details.
The analog inputs can be configured as




Figure 29A, single-ended referenced to system ground;
CFG[12:10] = 1112.
In this configuration, all inputs (IN[7:0]) have a range of
GND to VREF.
Figure 29B, bipolar differential with a common reference
point; COM = VREF/2; CFG[12:10] = 0102.
Unipolar differential with COM connected to a ground
sense; CFG[12:10] = 1102.
In these configurations, all inputs IN[7:0] have a range of
GND to VREF.
Figure 29C, bipolar differential pairs with the negative
input channel referenced to VREF/2; CFG[12:10] = 00X2.
Unipolar differential pairs with the negative input channel
referenced to a ground sense; CFG[12:10] = 10X2.
In these configurations, the positive input channels have
the range of GND to VREF. The negative input channels are
senses referred to VREF/2 for bipolar pairs, or GND for
unipolar pairs. The positive channel is configured with
CFG[9:7]. If CFG[9:7] is even, then IN0, IN2, IN4, and IN6
are used. If CFG[9:7] is odd, then IN1, IN3, IN5, and IN7
are used (channels with parentheses). For example, for
IN0/IN1 pairs with the positive channel on IN0, CFG[9:7]
= 0002. For IN4/IN5 pairs with the positive channel on
IN5, CFG[9:7] = 1012.
Note that for the sequencer, detailed in the Channel
Sequencer section, the positive channels are always IN0,
IN2, IN4, and IN6.
Figure 29D, inputs configured in any of the preceding
combinations (showing that the AD7949 can be configured
dynamically).
CH0+
IN0
CH0+
CH1+
IN1
CH1+
IN1
CH2+
IN2
CH2+
IN2
CH3+
IN3
CH3+
IN3
CH4+
IN4
CH4+
IN4
CH5+
IN5
CH5+
IN5
CH6+
IN6
CH6+
IN6
CH7+
IN7
CH7+
IN7
COM
COM–
COM
GND
A—8 CHANNELS,
SINGLE ENDED
IN0
GND
B—8 CHANNELS,
COMMON REFERNCE
CH0+ (–)
IN0
CH0+ (–)
CH0– (+)
IN1
CH0– (+)
IN1
CH1+ (–)
IN2
CH1+ (–)
IN2
CH1– (+)
IN3
CH1– (+)
IN3
CH2+ (–)
IN4
CH2+
IN4
CH2– (+)
IN5
CH3+
IN5
CH3+ (–)
IN6
CH4+
IN6
CH3– (+)
IN7
CH5+
IN7
COM
GND
C—4 CHANNELS,
DIFFERENTIAL
COM–
IN0
COM
GND
D—COMBINATION
07351-029
Input Configurations
Figure 29. Multiplexed Analog Input Configurations
Sequencer
The AD7949 includes a channel sequencer useful for scanning
channels in a repeated fashion. Refer to the Channel Sequencer
section for further details of the sequencer operation.
Source Resistance
When the source impedance of the driving circuit is low, the
AD7949 can be driven directly. Large source impedances
significantly affect the ac performance, especially THD. The dc
performances are less sensitive to the input impedance. The
maximum source impedance depends on the amount of THD
that can be tolerated. The THD degrades as a function of the
source impedance and the maximum input frequency.
Rev. B | Page 17 of 32
AD7949
DRIVER AMPLIFIER CHOICE
VOLTAGE REFERENCE OUTPUT/INPUT
Although the AD7949 is easy to drive, the driver amplifier must
meet the following requirements:
The AD7949 allows the choice of a very low temperature drift
internal voltage reference, an external reference, or an external
buffered reference.


The noise generated by the driver amplifier must be kept as
low as possible to preserve the SNR and transition noise
performance of the AD7949. Note that the AD7949 has a
noise much lower than most of the other 14-bit ADCs and,
therefore, can be driven by a noisier amplifier to meet a
given system noise specification. The noise from the
amplifier is filtered by the AD7949 analog input circuit
low-pass filter made by RIN and CIN or by an external filter,
if one is used.
For ac applications, the driver should have a THD performance commensurate with the AD7949. Figure 17 shows
THD vs. frequency for the AD7949.
For multichannel, multiplexed applications on each input
or input pair, the driver amplifier and the AD7949 analog
input circuit must settle a full-scale step onto the capacitor
array at a 14-bit level (0.0015%). In amplifier data sheets,
settling at 0.1% to 0.01% is more commonly specified. This
may differ significantly from the settling time at a 14-bit
level and should be verified prior to driver selection.
Table 8. Recommended Driver Amplifiers
Amplifier
ADA4841-x
AD8655
AD8021
AD8022
OP184
AD8605, AD8615
Typical Application
Very low noise, small, and low power
5 V single supply, low noise
Very low noise and high frequency
Low noise and high frequency
Low power, low noise, and low frequency
5 V single supply, low power
The internal reference of the AD7949 provides excellent
performance and can be used in almost all applications. There
are six possible choices of voltage reference schemes briefly
described in Table 9, with more details in each of the following
sections.
Internal Reference/Temperature Sensor
The precision internal reference, suitable for most applications,
can be set for either a 2.5 V or a 4.096 V output, as detailed in
Table 9. With the internal reference enabled, the band gap
voltage is also present on the REFIN pin, which requires an
external 0.1 μF capacitor. Because the current output of REFIN
is limited, it can be used as a source if followed by a suitable
buffer, such as the AD8605. Note that the voltage of REFIN
changes depending on the 2.5 V or 4.096 V internal reference.
Enabling the reference also enables the internal temperature
sensor, which measures the internal temperature of the AD7949
and is thus useful for performing a system calibration. Note
that, when using the temperature sensor, the output is straight
binary referenced from the AD7949 GND pin.
The internal reference is temperature-compensated to within
10 mV. The reference is trimmed to provide a typical drift of
±10 ppm/°C.
Connect the AD7949 as shown in Figure 30 for either a 2.5 V or
4.096 V internal reference.
10µF
100nF
REF
REFIN
AD7949
TEMP
GND
07351-030

Figure 30. 2.5 V or 4.096 V Internal Reference Connection
Rev. B | Page 18 of 32
AD7949
External Reference and Internal Buffer
Reference Decoupling
For improved drift performance, an external reference can be
used with the internal buffer, as shown in Figure 31. The
external source is connected to REFIN, the input to the on-chip
unity gain buffer, and the output is produced on the REF pin.
An external reference can be used with the internal buffer with
or without the temperature sensor enabled. Refer to Table 9 for
register details. With the buffer enabled, the gain is unity and
is limited to an input/output of VDD = −0.2 V; however, the
maximum voltage allowable must be ≤(VDD − 0.5 V).
Whether using an internal or external reference, the AD7949
voltage reference output/input, REF, has a dynamic input
impedance and should therefore be driven by a low impedance
source with efficient decoupling between the REF and GND
pins. This decoupling depends on the choice of the voltage
reference but usually consists of a low ESR capacitor connected
to REF and GND with minimum parasitic inductance. A 10 μF
(X5R, 1206 size) ceramic chip capacitor is appropriate when
using the internal reference, the ADR43x/ADR44x external
reference, or a low impedance buffer such as the AD8031 or
the AD8605.
The internal reference buffer is useful in multiconverter applications because a buffer is typically required in these applications.
In addition, a low power reference can be used because the
internal buffer provides the necessary performance to drive the
SAR architecture of the AD7949.
REF SOURCE
≤ (VDD – 0.5V)
10µF
100nF
REF
REFIN
If desired, smaller reference decoupling capacitor values down
to 2.2 μF can be used with minimal impact on performance,
especially on DNL.
AD7949
07351-031
TEMP
GND
The placement of the reference decoupling capacitor is also important to the performance of the AD7949, as explained in the
Layout section. Mount the decoupling capacitor on the same side
as the ADC at the REF pin with a thick PCB trace. The GND
should also be connected to the reference decoupling capacitor
with the shortest distance and to the analog ground plane with
several vias.
Regardless, there is no need for an additional lower value ceramic
decoupling capacitor (for example, 100 nF) between the REF
and GND pins.
Figure 31. External Reference Using Internal Buffer
External Reference
In any of the six voltage reference schemes, an external reference
can be connected directly on the REF pin as shown in Figure 32
because the output impedance of REF is >5 kΩ. To reduce power
consumption, the reference and buffer should be powered down.
For applications requiring the use of the temperature sensor,
the internal reference must be active (internal buffer can be
disabled in this case). Refer to Table 9 for register details. For
improved drift performance, an external reference such as the
ADR43x or ADR44x is recommended.
For applications that use multiple AD7949 devices or other
PulSAR devices, it is more effective to use the internal reference
buffer to buffer the external reference voltage, thus reducing
SAR conversion crosstalk.
The voltage reference temperature coefficient (TC) directly
impacts full scale; therefore, in applications where full-scale
accuracy matters, care must be taken with the TC. For instance,
a ±10 ppm/°C TC of the reference changes full scale by ±1 LSB/°C.
REF SOURCE
0.5V < REF < (VDD + 0.3V)
10µF
REF
TEMP
GND
07351-032
AD7949
NO CONNECTION
REQUIRED
REFIN
Figure 32. External Reference
Note that the best SNR is achieved with a 5 V external reference
as the internal reference is limited to 4.096 V. The SNR
degradation is as follows:
SNR LOSS  20 log
4.096
5
Rev. B | Page 19 of 32
AD7949
POWER SUPPLY
SUPPLYING THE ADC FROM THE REFERENCE
The AD7949 uses two power supply pins: an analog and digital
core supply (VDD) and a digital input/output interface supply
(VIO). VIO allows direct interface with any logic between 1.8 V
and VDD. To reduce the supplies needed, the VIO and VDD
pins can be tied together. The AD7949 is independent of power
supply sequencing between VIO and VDD. Additionally, it is
very insensitive to power supply variations over a wide
frequency range, as shown in Figure 33.
For simplified applications, the AD7949, with its low operating
current, can be supplied directly using an external reference
circuit like the one shown in Figure 35. The reference line can
be driven by:
75



The system power supply directly
A reference voltage with enough current output capability,
such as the ADR43x or ADR44x
A reference buffer, such as the AD8605, which can also
filter the system power supply, as shown in Figure 35
70
65
5V
5V
10Ω
5V
10kΩ
55
1µF
AD8605
1µF
10µF
0.1µF
50
1
45
REF
40
VDD
10
1
10k
1k
100
FREQUENCY (kHz)
07351-033
30
VIO
AD7949
35
1OPTIONAL
The AD7949 powers down automatically at the end of each
conversion phase; therefore, the operating currents and power
scale linearly with the sampling rate. This makes the part ideal
for low sampling rates (even of a few hertz) and low batterypowered applications.
10,000
VDD = 5V, INTERNAL REF
1000
100
VDD = 5V, EXTERNAL REF
10
VDD = 2.5V, EXTERNAL REF
1
VIO
0.1
10
100
1k
10k
SAMPLING RATE (SPS)
100k
1M
07351-034
0.010
0.001
REFERENCE BUFFER AND FILTER.
Figure 35. Example of an Application Circuit
Figure 33. PSRR vs. Frequency
OPERATING CURRENT (µA)
0.1µF
Figure 34. Operating Currents vs. Sampling Rate
Rev. B | Page 20 of 32
07351-035
PSSR (dB)
60
AD7949
DIGITAL INTERFACE
The AD7949 uses a simple 4-wire interface and is compatible
with SPI, MICROWIRE™, QSPI™, digital hosts, and DSPs, for
example, Blackfin® ADSP-BF53x, SHARC®, ADSP-219x, and
ADSP-218x.
The SCK frequency required is calculated by
The interface uses the CNV, DIN, SCK, and SDO signals and
allows CNV, which initiates the conversion, to be independent
of the readback timing. This is useful in low jitter sampling or
simultaneous sampling applications.
The time between tDATA and tCONV is a safe time when digital
activity should not occur, or sensitive bit decisions may be
corrupted.
A 14-bit register, CFG[13:0], is used to configure the ADC for
the channel to be converted, the reference selection, and other
components, which are detailed in the Configuration Register,
CFG, section.
When CNV is low, reading/writing can occur during conversion,
acquisition, and spanning conversion (acquisition plus conversion), as detailed in the following sections. The CFG word is
updated on the first 14 SCK rising edges, and conversion results
are output on the first 13 (or 14 if busy mode is selected) SCK
falling edges. If the CFG readback is enabled, an additional
14 SCK falling edges are required to output the CFG word
associated with the conversion results with the CFG MSB
following the LSB of the conversion result.
A discontinuous SCK is recommended because the part is
selected with CNV low, and SCK activity begins to write a new
configuration word and clock out data.
Note that in the following sections, the timing diagrams indicate
digital activity (SCK, CNV, DIN, SDO) during the conversion.
However, due to the possibility of performance degradation,
digital activity should occur only prior to the safe data reading/
writing time, tDATA, because the AD7949 provides error correction circuitry that can correct for an incorrect bit during this
time. From tDATA to tCONV, there is no error correction and conversion results may be corrupted. The user should configure the
AD7949 and initiate the busy indicator (if desired) prior to
tDATA. It is also possible to corrupt the sample by having SCK or
DIN transitions near the sampling instant. Therefore, it is
recommended to keep the digital pins quiet for approximately
20 ns before and 10 ns after the rising edge of CNV, using a
discontinuous SCK whenever possible to avoid any potential
performance degradation.
READING/WRITING DURING CONVERSION, FAST
HOSTS
When reading/writing during conversion (n), conversion
results are for the previous (n − 1) conversion, and writing the
CFG register is for the next (n + 1) acquisition and conversion.
After the CNV is brought high to initiate conversion, it must be
brought low again to allow reading/writing during conversion.
Reading/writing should only occur up to tDATA and, because this
time is limited, the host must use a fast SCK.
f SCK 
Number _ SCK _ Edges
t DATA
READING/WRITING AFTER CONVERSION, ANY
SPEED HOSTS
When reading/writing after conversion, or during acquisition
(n), conversion results are for the previous (n − 1) conversion,
and writing is for the (n + 1) acquisition.
For the maximum throughput, the only time restriction is that
the reading/writing take place during the tACQ (minimum) time.
For slow throughputs, the time restriction is dictated by the
throughput required by the user, and the host is free to run at
any speed. Thus for slow hosts, data access must take place
during the acquisition phase.
READING/WRITING SPANNING CONVERSION, ANY
SPEED HOST
When reading/writing spanning conversion, the data access starts
at the current acquisition (n) and spans into the conversion (n).
Conversion results are for the previous (n − 1) conversion, and
writing the CFG register is for the next (n + 1) acquisition and
conversion.
Similar to reading/writing during conversion, reading/writing
should only occur up to tDATA. For the maximum throughput,
the only time restriction is that reading/writing take place
during the tACQ + tDATA time.
For slow throughputs, the time restriction is dictated by the
user’s required throughput, and the host is free to run at any
speed. Similar to reading/writing during acquisition, for slow
hosts, the data access must take place during the acquisition
phase with additional time into the conversion.
Note that data access spanning conversion requires the CNV to
be driven high to initiate a new conversion, and data access is
not allowed when CNV is high. Thus, the host must perform
two bursts of data access when using this method.
CONFIGURATION REGISTER, CFG
The AD7949 uses a 14-bit configuration register (CFG[13:0]),
as detailed in Table 9, to configure the inputs, the channel to be
converted, the one-pole filter bandwidth, the reference, and the
channel sequencer. The CFG register is latched (MSB first) on
DIN with 14 SCK rising edges. The CFG update is edge dependent, allowing for asynchronous or synchronous hosts.
Rev. B | Page 21 of 32
AD7949



The register can be written to during conversion, during acquisition, or spanning acquisition/conversion, and is updated at the end
of conversion, tCONV (maximum). There is always a one deep
delay when writing the CFG register. Note that, at power-up, the
CFG register is undefined and two dummy conversions are
required to update the register. To preload the CFG register with a
factory setting, hold DIN high for two conversions. Thus
CFG[13:0] = 0x3FFF. This sets the AD7949 for the following:
13
CFG
12
INCC
11
INCC
10
INCC
9
INx
8
INx


IN[7:0] unipolar referenced to GND, sequenced in order
Full bandwidth for a one-pole filter
Internal reference/temperature sensor disabled, buffer
enabled
Enables the internal sequencer
No readback of the CFG register
Table 9 summarizes the configuration register bit details. See
the Theory of Operation section for more details.
7
INx
6
BW
5
REF
4
REF
3
REF
2
SEQ
1
SEQ
0
RB
Table 9. Configuration Register Description
Bit(s)
[13]
Name
CFG
[12:10]
INCC
[9:7]
INx
[6]
BW
[5:3]
REF
[2:1]
SEQ
[0]
RB
1
Description
Configuration update.
0 = keep current configuration settings.
1 = overwrite contents of register.
Input channel configuration. Selection of pseudo bipolar, pseudo differential, pairs, single-ended, or temperature sensor. Refer
to the Input Configurations section.
Bit 12
Bit 11
Bit 10
Function
0
0
X1
Bipolar differential pairs; INx− referenced to VREF/2 ± 0.1 V.
0
1
0
Bipolar; INx referenced to COM = VREF/2 ± 0.1 V.
0
1
1
Temperature sensor.
1
0
X1
Unipolar differential pairs; INx− referenced to GND ± 0.1 V.
1
1
0
Unipolar, INx referenced to COM = GND ± 0.1 V.
Unipolar, INx referenced to GND.
1
1
1
Input channel selection in binary fashion.
Bit 9
Bit 8
Bit 7
Channel
0
0
0
IN0
0
0
1
IN1
…
…
…
1
1
1
IN7
Select bandwidth for low-pass filter. Refer to the Selectable Low-Pass Filter section.
0 = ¼ of BW, uses an additional series resistor to further bandwidth limit the noise. Maximum throughput must also be reduced to ¼.
1 = full BW.
Reference/buffer selection. Selection of internal, external, external buffered, and enabling of the on-chip temperature sensor.
Refer to the Voltage Reference Output/Input section.
Bit 5
Bit 4
Bit 3
Function
0
0
0
Internal reference, REF = 2.5 V output.
0
0
1
Internal reference, REF = 4.096 V output.
0
1
0
External reference, temperature enabled.
0
1
1
External reference, internal buffer, temperature enabled.
1
1
0
External reference, temperature disabled.
1
1
1
External reference, internal buffer, temperature disabled.
Channel sequencer. Allows for scanning channels in an IN0 to IN[7:0] fashion. Refer to the Channel Sequencer section.
Bit 2
Bit 1
Function
0
0
Disable sequencer.
0
1
Update configuration during sequence.
1
0
Scan IN0 to IN[7:0] (set in CFG[9:7]), then temperature.
1
1
Scan IN0 to IN[7:0] (set in CFG[9:7]).
Read back the CFG register.
0 = read back current configuration at end of data.
1 = do not read back contents of configuration.
X = don’t care.
Rev. B | Page 22 of 32
AD7949
When CNV is brought low after EOC, SDO is driven from high
impedance to the MSB. Falling SCK edges clock out bits starting
with MSB − 1.
GENERAL TIMING WITHOUT A BUSY INDICATOR
Figure 36 details the timing for all three modes: read/write
during conversion (RDC), read/write after conversion (RAC),
and read/write spanning conversion (RSC). Note that the gating
item for both CFG and data readback is at the end of conversion
(EOC). At EOC, if CNV is high, the busy indicator is disabled.
The SCK can idle high or low depending on the clock polarity
(CPOL) and clock phase (CPHA) settings if SPI is used. A simple
solution is to use CPOL = CPHA = 0 as shown in Figure 36 with
SCK idling low.
As detailed previously in the Digital Interface section, the data
access should occur up to safe data reading/writing time, tDATA.
If the full CFG word was not written to prior to EOC, it is discarded and the current configuration remains. If the conversion
result is not read out fully prior to EOC, it is lost as the ADC
updates SDO with the MSB of the current conversion. For
detailed timing, refer to Figure 39 and Figure 40, which depict
reading/writing spanning conversion with all timing details,
including setup, hold, and SCK.
SOC
tCYC
POWER
UP
tCONV
CONVERSION
(n – 2) UNDEFINED
PHASE
From power-up, in any read/write mode, the first three conversion results are undefined because a valid CFG does not take
place until the 2nd EOC; thus two dummy conversions are
required. Also, if the state machine writes the CFG during the
power-up state (RDC shown), the CFG register needs to be
rewritten again at the next phase. Note that the first valid data
occurs in Phase (n + 1) when the CFG register is written during
Phase (n − 1).
EOC
EOC
EOC
EOC
tDATA
ACQUISITION
(n – 1) UNDEFINED
CONVERSION
(n – 1) UNDEFINED
ACQUISITION
(n)
CONVERSION
(n)
ACQUISITION
(n + 1)
CONVERSION
(n + 1)
ACQUISITION
(n + 2)
NOTE 1
CNV
DIN
CFG (n)
XXX
CFG (n + 1)
CFG (n + 2)
RDC
SDO
SCK
DATA (n – 3)
XXX
MSB
XXX
1
MSB
XXX
DATA (n – 2)
XXX
1
14
DATA (n – 1)
XXX
1
14
MSB
(n)
DATA (n)
1
14
14
NOTE 2
NOTE 1
CNV
CFG (n)
DIN
RAC
SDO
SCK
CFG (n + 1)
DATA (n – 2)
XXX
1
CFG (n + 2)
CFG (n + 3)
DATA (n)
DATA (n + 1)
DATA (n – 1)
XXX
14
1
14
1
1
14
NOTE 2
NOTE 1
CNV
RSC
DIN
CFG (n)
SDO
DATA (n – 2)
XXX
SCK
1
n
CFG (n)
DATA (n – 2)
XXX
n+1
14
1
CFG (n + 1)
CFG (n + 1)
DATA (n – 1)
XXX
DATA (n – 1)
XXX
n
n+1
14
CFG (n + 2)
CFG (n + 2)
CFG (n + 3)
DATA (n)
DATA (n)
DATA (n + 1)
1
n
n+1
14
1
n
NOTES
1. CNV MUST BE HIGH PRIOR TO THE END OF CONVERSION (EOC) TO AVOID THE BUSY INDICATOR.
2. A TOTAL OF 14 SCK FALLING EDGES ARE REQUIRED TO RETURN SDO TO HIGH-Z. IF CFG READBACK IS ENABLED, A TOTAL OF 28 SCK FALLING EDGES IS
REQUIRED TO RETURN SDO TO HIGH-Z.
3. WITH THE SEQUENCER ENABLED, THE NEXT ACQUISITION PHASE WILL BE FOR IN0 AFTER THE LAST CHANNEL SET IN CFG[9:7] IS CONVERTED.
Figure 36. General Interface Timing for the AD7949 Without a Busy Indicator
Rev. B | Page 23 of 32
07351-036
NOTE 2
AD7949
generation requires either a high impedance or a remaining bit
high-to-low transition. Because most SPI hosts are usually
limited to 8-bit or 16-bit bursts, this should not be an issue.
Additional clocks are not a concern because SDO remains high
impedance after the 15th falling edge.
GENERAL TIMING WITH A BUSY INDICATOR
Figure 37 details the timing for all three modes: read/write
during conversion (RDC), read/write after conversion (RAC),
and read/write spanning conversion (RSC). Note that the gating
item for both CFG and data readback is at the end of conversion
(EOC). As detailed previously, the data access should occur up
to safe data reading/writing time, tDATA. If the full CFG word is
not written to prior to EOC, it is discarded and the current
configuration remains.
The SCK can idle high or low depending on the CPOL and
CPHA settings if SPI is used. A simple solution is to use CPOL
= CPHA = 1 (not shown) with SCK idling high.
From power-up, in any read/write mode, the first three conversion results are undefined because a valid CFG does not take
place until the 2nd EOC; thus, two dummy conversions are
required. Also, if the state machine writes the CFG during the
power-up state (RDC shown), the CFG register needs to be
rewritten again at the next phase. Note that the first valid data
occurs in Phase (n + 1) when the CFG register is written during
Phase (n − 1).
At the EOC, if CNV is low, the busy indicator is enabled. In
addition, to generate the busy indicator properly, the host must
assert a minimum of 15 SCK falling edges to return SDO to
high impedance because the last bit on SDO remains active.
Unlike the case detailed in the General Timing Without a Busy
Indicator section, if the conversion result is not read out fully
prior to EOC, the last bit clocked out remains. If this bit is low,
the busy signal indicator cannot be generated because the busy
START OF CONVERSION
(SOC)
tCYC
POWER
UP
PHASE
tCONV
CONVERSION
(n – 2) UNDEFINED
EOC
EOC
EOC
EOC
tDATA
CONVERSION
(n – 1) UNDEFINED
ACQUISITION
(n – 1) UNDEFINED
CONVERSION
(n)
ACQUISITION
(n)
CONVERSION
(n + 1)
ACQUISITION
(n + 1)
ACQUISITION
(n + 2)
NOTE 1
CNV
DIN
XXX
CFG (n)
CFG (n + 1)
CFG (n + 2)
RDC
DATA (n – 3)
XXX
SDO
SCK
1
DATA (n – 1)
XXX
DATA (n – 2)
XXX
1
15
1
15
DATA (n)
1
15
15
NOTE 2
CNV
NOTE 1
DIN
CFG (n)
CFG (n + 1)
CFG (n + 2)
CFG (n + 3)
RAC
DATA (n – 2)
XXX
SDO
SCK
1
DATA (n – 1)
XXX
1
15
DATA (n)
1
15
DATA (n + 1)
1
15
NOTE 2
CNV
NOTE 1
DIN
CFG (n + 2)
CFG (n + 1)
CFG (n)
CFG (n + 3)
RSC
SDO
SCK
DATA (n – 2)
XXX
DATA (n – 2)
XXX
1
n
n+1
15
DATA (n – 1)
XXX
1
n
DATA (n – 1)
XXX
n+1
15
DATA (n)
DATA (n)
1
n
n+1
15
DATA (n + 1)
1
Figure 37. General Interface Timing for the AD7949 With a Busy Indicator
Rev. B | Page 24 of 32
07351-037
NOTE 2
NOTES
1. CNV MUST BE LOW PRIOR TO THE END OF CONVERSION (EOC) TO GENERATE THE BUSY INDICATOR.
2. A TOTAL OF 15 SCK FALLING EDGES ARE REQUIRED TO RETURN SDO TO HIGH-Z. IF CFG READBACK IS ENABLED,
A TOTAL OF 29 SCK FALLING EDGES IS REQUIRED TO RETURN SDO TO HIGH-Z.
AD7949
Busy Indicator section for more details. The sequencer can also
be used with the busy indicator and details for these timings can
be found in the General Timing with a Busy Indicator section
and the Read/Write Spanning Conversion with a Busy Indicator
section.
CHANNEL SEQUENCER
The AD7949 includes a channel sequencer useful for scanning
channels in a repeated fashion. Channels are scanned as singles
or pairs, with or without the temperature sensor, after the last
channel is sequenced.
For sequencer operation, the CFG register should be set during
the (n − 1) phase after power-up. On phase (n), the sequencer
setting takes place and acquires IN0. The first valid conversion
result is available at phase (n + 1). After the last channel set in
CFG[9:7] is converted, the internal temperature sensor data is
output (if enabled), followed by acquisition of IN0.
The sequencer starts with IN0 and finishes with IN[7:0] set in
CFG[9:7]. For paired channels, the channels are paired depending on the last channel set in CFG[9:7]. Note that in sequencer
mode, the channels are always paired with the positive input on
the even channels (IN0, IN2, IN4, IN6), and with the negative
input on the odd channels (IN1, IN3, IN5, IN7). For example,
setting CFG[9:7] = 110 or 111 scans all pairs with the positive
inputs dedicated to IN0, IN2, IN4, and IN6.
Examples
With all channels configured for unipolar mode to GND,
including the internal temperature sensor, the sequence scans in
the following order:
CFG[2:1] are used to enable the sequencer. After the CFG
register is updated, DIN must be held low while reading data
out for Bit 13, or the CFG register begins updating again.
IN0, IN1, IN2, IN3, IN4, IN5, IN6, IN7, TEMP, IN0, IN1, IN2, …
Note that while operating in a sequence, some bits of the CFG
register can be changed. However, if changing CFG[11] (paired
or single channel) or CFG[9:7] (last channel in sequence), the
sequence reinitializes and converts IN0 (or IN0/IN1 pairs) after
the CFG register is updated.
For paired channels with the internal temperature sensor
enabled, the sequencer scans in the following order:
IN0, IN2, IN4, IN6, TEMP, IN0, …
Note that IN1, IN3, IN5, and IN7 are referenced to a GND
sense or VREF/2, as detailed in the Input Configurations section.
Figure 38 details the timing for all three modes without a busy
indicator. Refer to the General Timing Without a Busy Indicator
section and the Read/Write Spanning Conversion Without a
SOC
tCYC
POWER
UP
tCONV
CONVERSION
(n – 2) UNDEFINED
PHASE
EOC
EOC
EOC
EOC
tDATA
ACQUISITION
(n – 1) UNDEFINED
CONVERSION
(n – 1) UNDEFINED
ACQUISITION
(n), IN0
CONVERSION
(n), IN0
ACQUISITION
(n + 1), IN1
CONVERSION
(n + 1), IN1
ACQUISITION
(n + 2), IN2
NOTE 1
CNV
DIN
CFG (n)
XXX
RDC
SDO
SCK
MSB
XXX
1
MSB
XXX
DATA (n – 2)
XXX
DATA (n – 3)
XXX
1
14
MSB
IN0
DATA (n – 1)
XXX
1
14
DATA IN0
1
14
14
NOTE 2
NOTE 1
CNV
CFG (n)
DIN
RAC
DATA (n – 2)
XXX
SDO
SCK
DATA (n – 1)
XXX
14
1
1
DATA IN0
14
DATA IN1
14
1
1
NOTE 2
NOTE 1
CNV
DIN
CFG (n)
SDO
DATA (n – 2)
XXX
SCK
1
n
CFG (n)
DATA (n – 2)
XXX
n+1
14
DATA (n – 1)
XXX
1
n
DATA (n – 1)
XXX
n+1
14
DATA IN0
DATA IN0
1
n
n+1
14
DATA IN1
1
n
NOTE 2
NOTES
1. CNV MUST BE HIGH PRIOR TO THE END OF CONVERSION (EOC) TO AVOID THE BUSY INDICATOR.
2. A TOTAL OF 14 SCK FALLING EDGES ARE REQUIRED TO RETURN SDO TO HIGH-Z. IF CFG READBACK IS ENABLED,
A TOTAL OF 28 SCK FALLING EDGES IS REQUIRED TO RETURN SDO TO HIGH-Z.
Figure 38. General Channel Sequencer Timing Without a Busy Indicator
Rev. B | Page 25 of 32
07351-038
RSC
AD7949
low after tCONV (maximum), the MSB is enabled on SDO. The
host also must enable the MSB of the CFG register at this time
(if necessary) to begin the CFG update. While CNV is low, both
a CFG update and a data readback take place. The first 14 SCK
rising edges are used to update the CFG, and the first 13 SCK
falling edges clock out the conversion results starting with
MSB − 1. The restriction for both configuring and reading is
that they both must occur before the tDATA time of the next conversion elapses. All 14 bits of CFG[13:0] must be written, or they
are ignored. In addition, if the 14-bit conversion result is not
read back before tDATA elapses, it is lost.
READ/WRITE SPANNING CONVERSION WITHOUT
A BUSY INDICATOR
This mode is used when the AD7949 is connected to any host
using an SPI, serial port, or FPGA. The connection diagram is
shown in Figure 39, and the corresponding timing is given in
Figure 40. For the SPI, the host should use CPHA = CPOL = 0.
Reading/writing spanning conversion is shown, which covers
all three modes detailed in the Digital Interface section. For this
mode, the host must generate the data transfer based on the
conversion time. For an interrupt driven transfer that uses a
busy indicator, refer to the Read/Write Spanning Conversion
with a Busy Indicator section.
The SDO data is valid on both SCK edges. Although the rising
edge can be used to capture the data, a digital host using the
SCK falling edge allows a faster reading rate, provided it has an
acceptable hold time. After the 14th (or 28th) SCK falling edge, or
when CNV goes high (whichever occurs first), SDO returns to
high impedance.
A rising edge on CNV initiates a conversion, forces SDO to
high impedance, and ignores data present on DIN. After a
conversion is initiated, it continues until completion irrespective of the state of CNV. CNV must be returned high before the
safe data transfer time, tDATA, and then held high beyond the
conversion time, tCONV, to avoid generation of the busy signal
indicator.
If CFG readback is enabled, the CFG register associated with the
conversion result is read back MSB first following the LSB of the
conversion result. A total of 28 SCK falling edges is required to
return SDO to high impedance if this is enabled.
After the conversion is complete, the AD7949 enters the
acquisition phase and power-down. When the host brings CNV
CNV
SS
SDO
MISO
DIN
MOSI
SCK
SCK
FOR SPI USE CPHA = 0, CPOL = 0.
07351-039
DIGITAL HOST
AD7949
Figure 39. Connection Diagram for the AD7949 Without a Busy Indicator
tCYC
> tCONV
tCONV
tCONV
tDATA
tDATA
tCNVH
EOC
EOC
RETURN CNV HIGH
FOR NO BUSY
RETURN CNV HIGH
FOR NO BUSY
CNV
tACQ
(QUIET
TIME)
CONVERSION (n – 1)
tSCK
tSCKH
SCK
12
UPDATE (n)
CFG/SDO
13
14/
28
CFG
LSB
DIN
X
1
tEN END CFG (n)
SDO
END DATA (n – 2)
12
13
14/
28
X
X
tHDIN
CFG
MSB – 1
CFG
LSB
BEGIN CFG (n + 1) tHSDO
tEN
tDSDO
tEN
END CFG (n + 1)
SEE NOTE
MSB
LSB
tDIS
2
tSDIN
CFG
MSB
X
tDIS
UPDATE (n + 1)
CFG/SDO
SEE NOTE
tCLSCK
tSCKL
(QUIET
TIME)
CONVERSION (n)
ACQUISITION (n)
LSB
BEGIN DATA (n – 1)
tDIS
END DATA (n – 1)
NOTES
1. THE LSB IS FOR CONVERSION RESULTS OR THE CONFIGURATION REGISTER CFG (n – 1) IF
13 SCK FALLING EDGES = LSB OF CONVERSION RESULTS.
27 SCK FALLING EDGES = LSB OF CONFIGURATION REGISTER.
ON THE 14TH OR 28TH SCK FALLING EDGE, SDO IS DRIVEN TO HIGH IMPEDANCE.
Figure 40. Serial Interface Timing for the AD7949 Without a Busy Indicator
Rev. B | Page 26 of 32
tDIS
07351-040
ACQUISITION
(n - 1)
AD7949
CFG update. While CNV is low, both a CFG update and a data
readback take place. The first 14 SCK rising edges are used to
update the CFG register, and the first 14 SCK falling edges clock
out the conversion results starting with the MSB. The restriction for both configuring and reading is that they both occur
before the tDATA time elapses for the next conversion. All 14 bits of
CFG[13:0] must be written or they are ignored. Also, if the 14-bit
conversion result is not read back before tDATA elapses, it is lost.
READ/WRITE SPANNING CONVERSION WITH A
BUSY INDICATOR
This mode is used when the AD7949 is connected to any host
using an SPI, serial port, or FPGA with an interrupt input. The
connection diagram is shown in Figure 41, and the corresponding timing is given in Figure 42. For the SPI, the host should use
CPHA = CPOL = 1. Reading/writing spanning conversion is
shown, which covers all three modes detailed in the Digital
Interface section.
The SDO data is valid on both SCK edges. Although the rising
edge can be used to capture the data, a digital host using the
SCK falling edge allows a faster reading rate, provided it has an
acceptable hold time. After the optional 15th (or 29st) SCK
falling edge, SDO returns to high impedance. Note that if the
optional SCK falling edge is not used, the busy feature cannot
be detected, as described in the General Timing with a Busy
Indicator section.
A rising edge on CNV initiates a conversion, ignores data
present on DIN and forces SDO to high impedance. After the
conversion is initiated, it continues until completion irrespective of the state of CNV. CNV must be returned low before the
safe data transfer time, tDATA, and then held low beyond the
conversion time, tCONV, to generate the busy signal indicator.
When the conversion is complete, SDO transitions from high
impedance to low (data ready), and with a pull-up to VIO, SDO
can be used to interrupt the host to begin data transfer.
If CFG readback is enabled, the CFG register associated with
the conversion result is read back MSB first following the LSB of
the conversion result. A total of 29 SCK falling edges is required
to return SDO to high impedance if this is enabled.
After the conversion is complete, the AD7949 enters the
acquisition phase and power-down. The host must enable the
MSB of the CFG register at this time (if necessary) to begin the
VIO
AD7949
DIGITAL HOST
SDO
MISO
IRQ
DIN
MOSI
SCK
SCK
07351-041
SS
CNV
FOR SPI USE CPHA = 1, CPOL = 1.
Figure 41. Connection Diagram for the AD7949 with a Busy Indicator
tCYC
tCONV
tACQ
tDATA
tDATA
tCNVH
CNV
(QUIET
TIME)
CONVERSION (n – 1)
tSCK
tSCKH
SCK
13
14
15/
29
13
14
15/
29
X
X
X
tHDIN
tSDIN
X
X
LSB
+1
END DATA (n – 2)
CFG
CFG
MSB MSB –1
X
tDIS
END CFG (n)
SDO
2
ACQUISITION
(n + 1)
UPDATE (n + 1)
CFG/SDO
NOTE 1
1
tSCKL
DIN
(QUIET
TIME)
CONVERSION (n)
ACQUISITION (n)
UPDATE (n)
CFG/SDO
BEIGN CFG (n + 1)
MSB
LSB
tEN
tHSDO
tDSDO
tEN
MSB
–1
BEGIN DATA (n – 1)
LSB
+1
tDIS
LSB
END DATA (n – 1) NOTE 1
NOTES:
1. THE LSB IS FOR CONVERSION RESULTS OR THE CONFIGURATION REGISTER CFG (n – 1) IF
14 SCK FALLING EDGES = LSB OF CONVERSION RESULTS.
28 SCK FALLING EDGES = LSB OF CONFIGURATION REGISTER.
ON THE 15TH OR 29TH SCK FALLING EDGE, SDO IS DRIVEN TO HIGH IMPEDANCE.
OTHERWISE, THE LSB REMAINS ACTIVE UNTIL THE BUSY INDICATOR IS DRIVEN LOW.
Figure 42. Serial Interface Timing for the AD7949 with a Busy Indicator
Rev. B | Page 27 of 32
tDIS
END CFG (n + 1)
tEN
07351-042
CONVERSION
(n – 1)
AD7949
APPLICATION HINTS
LAYOUT
The printed circuit board (PCB) that houses the AD7949 should
be designed so that the analog and digital sections are separated
and confined to certain areas of the board. The pinout of the
AD7949, with all its analog signals on the left side and all its
digital signals on the right side, eases this task.
Avoid running digital lines under the device because these couple
noise onto the die unless a ground plane under the AD7949 is
used as a shield. Fast switching signals, such as CNV or clocks,
should not run near analog signal paths. Avoid crossover of
digital and analog signals.
At least one ground plane should be used. It can be common or
split between the digital and analog sections. In the latter case,
the planes should be joined underneath the AD7949.
The AD7949 voltage reference input REF has a dynamic input
impedance and should be decoupled with minimal parasitic
inductances. This is done by placing the reference decoupling
ceramic capacitor close to, ideally right up against, the REF and
GND pins and connecting them with wide, low impedance traces.
Finally, the power supplies VDD and VIO of the AD7949
should be decoupled with ceramic capacitors, typically 100 nF,
placed close to the AD7949, and connected using short, wide
traces to provide low impedance paths and to reduce the effect
of glitches on the power supply lines.
EVALUATING AD7949 PERFORMANCE
Other recommended layouts for the AD7949 are outlined in the
documentation of the evaluation board for the AD7949 (EVALAD7949EDZ). The evaluation board package includes a fully
assembled and tested evaluation board, documentation, and
software for controlling the board from a PC via the converter and
evaluation development data capture board, EVAL-CED1Z.
Rev. B | Page 28 of 32
AD7949
OUTLINE DIMENSIONS
0.60 MAX
4.00
BSC SQ
0.60 MAX
15
PIN 1
INDICATOR
20
16
1
PIN 1
INDICATOR
3.75
BSC SQ
0.50
BSC
2.65
2.50 SQ
2.35
EXPOSED
PAD
(BOTTOM VIEW)
5
10
1.00
0.85
0.80
12° MAX
0.80 MAX
0.65 TYP
0.30
0.23
0.18
SEATING
PLANE
0.50
0.40
0.30
0.05 MAX
0.02 NOM
COPLANARITY
0.08
0.20 REF
0.25 MIN
FOR PROPER CONNECTION OF
THE EXPOSED PAD, REFER TO
THE PIN CONFIGURATION AND
FUNCTION DESCRIPTIONS
SECTION OF THIS DATA SHEET.
COMPLIANT TO JEDEC STANDARDS MO-220-VGGD-1
090408-B
TOP VIEW
6
11
Figure 43. 20-Lead Lead Frame Chip Scale Package (LFCSP_VQ)
4 mm × 4 mm Body, Very Thin Quad
(CP-20-4)
Dimensions shown in millimeters
ORDERING GUIDE
Model
AD7949BCPZ1
AD7949BCPZRL71
EVAL-AD7949EDZ1
EVAL-CED1Z1, 2
1
2
Temperature
Range
–40°C to +85°C
–40°C to +85°C
Package Description
20-Lead LFCSP_VQ
20-Lead LFCSP_VQ
Evaluation Board
Controller Board
Package
Option
CP-20-4
CP-20-4
Z = RoHS Compliant Part.
This controller board allows a PC to control and communicate with all Analog Devices evaluation boards whose model numbers end in ED.
Rev. B | Page 29 of 32
Ordering
Quantity
Tray, 490
Reel, 1,500
AD7949
NOTES
Rev. B | Page 30 of 32
AD7949
NOTES
Rev. B | Page 31 of 32
AD7949
NOTES
©2008–2009 Analog Devices, Inc. All rights reserved. Trademarks and
registered trademarks are the property of their respective owners.
D07351-0-5/09(B)
Rev. B | Page 32 of 32