Low-Power, 8-Channel, 24-Bit Analog Front

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ADS1294, ADS1294R, ADS1296, ADS1296R, ADS1298, ADS1298R
SBAS459K – JANUARY 2010 – REVISED AUGUST 2015
ADS129x Low-Power, 8-Channel, 24-Bit Analog Front-End for Biopotential Measurements
1 Features
3 Description
•
The ADS1294, ADS1296, ADS1298 (ADS129x) and
ADS1294R, ADS1296R ADS1298R (ADS129xR) are
a family of multichannel, simultaneous sampling,
24-bit, delta-sigma (ΔΣ) analog-to-digital converters
(ADCs) with built-in programmable gain amplifiers
(PGAs), internal reference, and an onboard oscillator.
The ADS129x and ADS129xR incorporate all of the
features that are commonly required in medical
electrocardiogram (ECG) and electroencephalogram
(EEG) applications. With high levels of integration
and exceptional performance, the ADS129x and
ADS129xR enables the development of scalable
medical instrumentation systems at significantly
reduced size, power, and overall cost.
1
•
•
•
•
•
•
•
•
•
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Eight Low-Noise PGAs and Eight High-Resolution
ADCs (ADS1298, ADS1298R)
Low Power: 0.75 mW/channel
Input-Referred Noise: 4 μVPP (150 Hz BW, G = 6)
Input Bias Current: 200 pA
Data Rate: 250 SPS to 32 kSPS
CMRR: –115 dB
Programmable Gain: 1, 2, 3, 4, 6, 8, or 12
Supports systems meeting AAMI EC11, EC13,
IEC60601-1, IEC60601-2-27, and IEC60601-2-51
Standards
Unipolar or Bipolar Supplies:
– AVDD = 2.7 V to 5.25 V
– DVDD = 1.65 V to 3.6 V
Built-In Right Leg Drive Amplifier, Lead-Off
Detection, Wilson Center Terminal, Pace
Detection, Test Signals
Integrated Respiration Impedance Measurement
Digital Pace Detection Capability
Built-In Oscillator and Reference
SPI™-Compatible Serial Interface
2 Applications
•
Medical Instrumentation (ECG, EMG, and EEG):
Patient Monitoring; Holter, Event, Stress, and Vital
Signs Including ECG, AED, Telemedicine
Bispectral Index (BIS), Evoked Audio Potential
(EAP), Sleep Study Monitor
Simplified Schematic
REF
Test Signals and
Monitors
Reference
ADS129xR
A1
SPI
ADC1
ADC2
A3
ADC3
A4
ADC4
A5
ADC5
A6
ADC6
A7
ADC7
INPUTS
Package options include a tiny 8-mm × 8-mm,
64-ball BGA, and a TQFP-64. The ADS129x BGA
version is specified over the commercial temperature
range of 0°C to 70°C. The ADS129xR BGA and
ADS129x TQFP versions are specified over the
industrial temperature range of –40°C to +85°C.
Device Information(1)
CLK
A2
SPI
RESP
DEMOD
The ADS129x and ADS129xR have a flexible input
multiplexer (mux) per channel that can be
independently connected to the internally-generated
signals for test, temperature, and lead-off detection.
Additionally, any configuration of input channels can
be selected for derivation of the right leg drive (RLD)
output signal. The ADS129x and ADS129xR operate
at data rates as high as 32 kSPS, thereby allowing
the implementation of software pace detection. Leadoff detection can be implemented internal to the
device, either with a pullup or pulldown resistor, or an
excitation current sink or source. Three integrated
amplifiers generate the Wilson central terminal (WCT)
and the Goldberger central terminals (GCT) required
for a standard 12-lead ECG. The ADS129xR versions
include a fully integrated, respiration impedance
measurement function. Multiple ADS129x and
ADS129xR devices can be cascaded in high channel
count systems in a daisy-chain configuration.
Oscillator
PART NUMBER
ADS129x,
ADS129xR
MUX
Control
PACKAGE
BODY SIZE (NOM)
NFBGA (64)
8.00 mm × 8.00 mm
TQFP (64)
10.00 mm × 10.00 mm
GPIO AND CONTROL
(1) For all available packages, see the package option addendum
at the end of the data sheet.
ADC8
A8
To Channel
WCT
RESP
Wilson
Terminal
¼
¼
Resp
¼
ADS129xR
RLD
PACE
1
An IMPORTANT NOTICE at the end of this data sheet addresses availability, warranty, changes, use in safety-critical applications,
intellectual property matters and other important disclaimers. PRODUCTION DATA.
ADS1294, ADS1294R, ADS1296, ADS1296R, ADS1298, ADS1298R
SBAS459K – JANUARY 2010 – REVISED AUGUST 2015
www.ti.com
Table of Contents
1
2
3
4
5
6
7
9.4 Device Functional Modes........................................ 51
9.5 Programming........................................................... 59
9.6 Register Maps ......................................................... 65
Features .................................................................. 1
Applications ........................................................... 1
Description ............................................................. 1
Revision History..................................................... 2
Device Comparison ............................................... 5
Pin Configuration and Functions ......................... 6
Specifications....................................................... 12
10 Application and Implementation........................ 84
7.1
7.2
7.3
7.4
7.5
7.6
7.7
7.8
12 Layout................................................................... 98
Absolute Maximum Ratings ....................................
ESD Ratings............................................................
Recommended Operating Conditions.....................
Thermal Information ................................................
Electrical Characteristics.........................................
Timing Requirements: Serial Interface....................
Switching Characteristics: Serial Interface..............
Typical Characteristics ............................................
12
12
12
13
13
17
17
18
8
Parameter Measurement Information ................ 22
9
Detailed Description ............................................ 24
8.1 Noise Measurements .............................................. 22
9.1 Overview ................................................................. 24
9.2 Functional Block Diagram ....................................... 25
9.3 Feature Description................................................. 26
10.1 Application Information.......................................... 84
10.2 Typical Applications .............................................. 89
11 Power Supply Recommendations ..................... 96
11.1 Power-Up Sequencing .......................................... 96
11.2 Connecting to Unipolar (3 V or 1.8 V) Supplies.... 97
11.3 Connecting to Bipolar (±1.5 V or ±1.8 V)
Supplies ................................................................... 97
12.1 Layout Guidelines ................................................. 98
12.2 Layout Example .................................................... 99
13 Device and Documentation Support ............... 100
13.1
13.2
13.3
13.4
13.5
Related Links ......................................................
Community Resources........................................
Trademarks .........................................................
Electrostatic Discharge Caution ..........................
Glossary ..............................................................
100
100
100
100
100
14 Mechanical, Packaging, and Orderable
Information ......................................................... 100
4 Revision History
NOTE: Page numbers for previous revisions may differ from page numbers in the current version.
Changes from Revision J (January 2014) to Revision K
Page
•
Added ESD Ratings table, Feature Description section, Device Functional Modes, Application and Implementation
section, Power Supply Recommendations section, Layout section, Device and Documentation Support section, and
Mechanical, Packaging, and Orderable Information section ................................................................................................. 1
•
Changed text throughout data sheet for clarity ...................................................................................................................... 1
•
Added note to DAISY_IN pin ................................................................................................................................................. 8
•
Added note to DAISY_IN pin ............................................................................................................................................... 10
•
Changed Equation 3 ............................................................................................................................................................ 32
Changes from Revision I (January 2012) to Revision J
Page
•
Changed NC pin discription in Pin Assignments table ......................................................................................................... 10
•
Changed NC pin discription in Pin Assignments table ......................................................................................................... 10
•
Added graph of INTERNAL VREF DRIFT vs TEMPERATURE ............................................................................................. 21
•
Changed order of subsections in the Theory of Operation section ...................................................................................... 26
•
Changed single-ended input description to correct input range values ............................................................................... 30
•
Changed Figure 27 to show correct input range for single-ended inputs ............................................................................ 30
•
Changed Figure 28 to show correct input range for single-ended inputs ............................................................................ 30
•
Deleted text regarding large scale signal ............................................................................................................................. 31
•
Changed Figure 32 to provide a more stable external reference driver circuit .................................................................... 33
•
Updated Figure 57 ............................................................................................................................................................... 51
•
Added Figure 58 .................................................................................................................................................................. 52
•
Added discussion of SCLK/DRDY bus behavior to Data Ready (DRDY) section................................................................ 53
•
Added Figure 60 .................................................................................................................................................................. 53
2
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SBAS459K – JANUARY 2010 – REVISED AUGUST 2015
•
Added status Word section and Figure 61 to discuss the status word ................................................................................ 53
•
Added Readback Length section.......................................................................................................................................... 53
•
Added SCLK Clocking Methods section............................................................................................................................... 60
•
Changed units in TEST_AMP bit description in CONFIG2 register ..................................................................................... 68
•
Changed Figure 93 to clarify Initial Flow at Power-Up ......................................................................................................... 85
•
Changed Power-Up Sequencing section text to clarify start-up timing ................................................................................ 96
•
Changed Figure 105 ............................................................................................................................................................ 96
•
Changed power-up reset wait time in Table 38 ................................................................................................................... 96
Changes from Revision H (October 2011) to Revision I
Page
•
Added eighth Features bullet (list of standards supported).................................................................................................... 1
•
Updated BGA pin out.............................................................................................................................................................. 6
•
Deleted duplicate Digital input voltage and Digital output voltage rows from Absolute Maximum Ratings table................. 12
•
Changed parameter name of Channel Performance, Common-mode rejection ratio and Power-supply rejection ratio
parameters in Electrical Characteristics table ...................................................................................................................... 14
•
Updated Functional Block Diagram ..................................................................................................................................... 25
•
Updated description of Analog Input section........................................................................................................................ 30
•
Updated Figure 30 ............................................................................................................................................................... 32
•
Updated Figure 33 ............................................................................................................................................................... 34
•
Updated Figure 34 ............................................................................................................................................................... 35
•
Changed description of START pin in START section......................................................................................................... 51
•
Changed description of Data Ready (DRDY) section .......................................................................................................... 52
•
Changed conversion description in Single-Shot Mode section ............................................................................................ 54
•
Changed conversion description in Continuous Mode section............................................................................................. 55
•
Changed Unit column in Table 14 ........................................................................................................................................ 55
•
Added power-down recommendation to bit 7 description of CHnSET: Individual Channel Settings section....................... 71
•
Changed description of bit 5 in RESP: Respiration Control Register section ...................................................................... 80
•
Corrected name of bit 6 in WCT2: Wilson Central Terminal Control Register section......................................................... 83
Changes from Revision G (February 2011) to Revision H
Page
•
Changed footnote 1 of BGA Pin Assignments table .............................................................................................................. 7
•
Added footnote 1 cross-reference to RLDIN, TESTP_PACE_OUT1, and TESTP_PACE_OUT in BGA Pin
Assignments table .................................................................................................................................................................. 7
•
Changed footnote 1 of PAG Pin Assignments table ............................................................................................................ 10
•
Added footnote 1 cross-reference to TESTP_PACE_OUT1, TESTP_PACE_OUT2, and RLDIN in PAG Pin
Assignments table ................................................................................................................................................................ 10
•
Changed description of AVSS and AVDD in PAG Pin Assignments table .......................................................................... 11
•
Added (ADS1298) to High-Resolution mode and Low-Power mode test conditions of Supply Current section in
Electrical Characteristics table ............................................................................................................................................. 16
•
Changed 3-V Power Dissipation, Quiescent channel power test conditions in Electrical Characteristics table .................. 16
•
Changed 5-V Power Dissipation, Quiescent channel power test conditions in Electrical Characteristics table .................. 16
•
Changed title of Figure 20 ................................................................................................................................................... 20
•
Updated Figure 42 ............................................................................................................................................................... 41
•
Added new paragraph to Respiration section ...................................................................................................................... 46
•
Updated Equation 5 ............................................................................................................................................................. 49
•
Changed title of Table 13 .................................................................................................................................................... 54
Copyright © 2010–2015, Texas Instruments Incorporated
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ADS1294, ADS1294R, ADS1296, ADS1296R, ADS1298, ADS1298R
SBAS459K – JANUARY 2010 – REVISED AUGUST 2015
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•
Updated Figure 66 ............................................................................................................................................................... 57
•
Changed description of STANDBY: Enter STANDBY Mode section ................................................................................... 61
•
Changed bit name for bits 5, 6, and 7 in ID register of Table 16 ........................................................................................ 65
•
Changed bit name for bits 5, 6, and 7 in ID: ID Control Register section ............................................................................ 66
•
Added footnote to Figure 97 ................................................................................................................................................ 89
•
Changed description of solid ceramic capacitor in Power Supplies and Grounding section ............................................... 96
•
Changed description of Connecting the Device to Bipolar (±1.5 V/1.8 V) Supplies section ................................................ 97
4
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Product Folder Links: ADS1294 ADS1294R ADS1296 ADS1296R ADS1298 ADS1298R
ADS1294, ADS1294R, ADS1296, ADS1296R, ADS1298, ADS1298R
www.ti.com
SBAS459K – JANUARY 2010 – REVISED AUGUST 2015
5 Device Comparison
PRODUCT
ADS1194
ADS1196
ADS1198
ADS1294
ADS1294R
ADS1296
ADS1296R
ADS1298
ADS1298R
PACKAGE
OPTIONS
OPERATING
TEMPERATURE
RANGE
TQFP-64
0°C to 70°C
NFBGA-64
0°C to 70°C
TQFP-64
0°C to 70°C
NFBGA-64
0°C to 70°C
TQFP-64
0°C to 70°C
NFBGA-64
0°C to 70°C
TQFP-64
–40°C to +85°C
NFBGA-64
0°C to 70°C
NFBGA-64
–40°C to +85°C
TQFP-64
–40°C to +85°C
NFBGA-64
0°C to 70°C
NFBGA-64
–40°C to +85°C
TQFP-64
–40°C to +85°C
NFBGA-64
0°C to 70°C
NFBGA-64
–40°C to +85°C
Copyright © 2010–2015, Texas Instruments Incorporated
CHANNELS
ADC
RESOLUTION
MAXIMUM
SAMPLING
RATE
No
4
16
8 kSPS
No
6
16
8 kSPS
No
8
16
8 kSPS
4
24
32 kSPS
6
24
32 kSPS
8
24
32 kSPS
RESPIRATION
CIRCUITRY
External
Yes
External
Yes
External
Yes
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ADS1294, ADS1294R, ADS1296, ADS1296R, ADS1298, ADS1298R
SBAS459K – JANUARY 2010 – REVISED AUGUST 2015
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6 Pin Configuration and Functions
ZXG Package
64-Pin NFBGA
Top View, Solder Bumps on Bottom Side
H
G
F
E
D
C
B
A
IN1P
IN2P
IN3P
IN4P
IN5P
IN6P
IN7P
IN8P
1
IN1N
IN2N
IN3N
IN4N
IN5N
IN6N
IN7N
IN8N
2
VREFP
VCAP4
TESTN_
PACE_OUT2
TESTP_
PACE_OUT1
WCT
RLDINV
RLDOUT
RLDIN
3
VREFN
RESP_
MODP
RESP_
MODN
RESV1
AVSS
RLDREF
AVDD
AVDD
4
VCAP1
PWDN
GPIO1
GPIO4
AVSS
AVSS
AVSS
AVSS
5
VCAP2
RESET
DAISY_IN
GPIO3
DRDY
AVDD
AVDD
AVDD
6
DGND
START
CS
GPIO2
DGND
DGND
VCAP3
AVDD1
7
DIN
CLK
SCLK
DOUT
DVDD
DVDD
CLKSEL
AVSS1
8
6
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SBAS459K – JANUARY 2010 – REVISED AUGUST 2015
Pin Function: NFBGA Package
PIN
TYPE
DESCRIPTION
NO.
NAME
1A
IN8P (1)
Analog input
Differential analog positive input 8 (ADS1298 and ADS1298R)
1B
IN7P (1)
Analog input
Differential analog positive input 7 (ADS1298 and ADS1298R)
1C
IN6P
(1)
Analog input
Differential analog positive input 6 (ADS1296, ADS1298, ADS1296R, ADS1298R)
1D
IN5P (1)
Analog input
Differential analog positive input 5 (ADS1296, ADS1298, ADS1296R, ADS1298R)
1E
IN4P (1)
Analog input
Differential analog positive input 4
1F
IN3P (1)
Analog input
Differential analog positive input 3
1G
IN2P
(1)
Analog input
Differential analog positive input 2
1H
IN1P (1)
Analog input
Differential analog positive input 1
2A
IN8N (1)
Analog input
Differential analog negative input 8 (ADS1298, ADS1298R)
2B
IN7N
(1)
Analog input
Differential analog negative input (ADS1298, ADS1298R)
2C
IN6N (1)
Analog input
Differential analog negative input 6 (ADS1296, ADS1298, ADS1296R, ADS1298R)
2D
IN5N (1)
Analog input
Differential analog negative input 5 (ADS1296, ADS1298, ADS1296R, ADS1298R)
2E
IN4N
(1)
Analog input
Differential analog negative input 4
2F
IN3N (1)
Analog input
Differential analog negative input 3
2G
IN2N (1)
Analog input
Differential analog negative input 2
2H
IN1N (1)
Analog input
Differential analog negative input 1
Analog input
Right leg drive input to mux
(1)
3A
RLDIN
3B
RLDOUT
Analog output
3C
RLDINV
Analog
input/output
Right leg drive inverting input
3D
WCT
Analog output
Wilson central terminal output
3E
TESTP_PACE_OUT1 (1)
Analog
input/buffer
output
Internal test signal or single-ended buffer output based on register settings
3F
TESTN_PACE_OUT2 (1)
Analog
input/output
Internal test signal or single-ended buffer output based on register settings
3G
VCAP4
—
3H
VREFP
Analog
input/output
4A
AVDD
Supply
Analog supply
Analog supply
Right leg drive output
Analog bypass capacitor; connect 1-μF capacitor to AVSS
Positive reference input/output voltage
4B
AVDD
Supply
4C
RLDREF
Analog input
4D
AVSS
Supply
4E
RESV1
Digital input
4F
RESP_MODN
Analog output
ADS129xR: modulation clock for respiration measurement, negative side.
ADS129x: leave floating.
4G
RESP_MODP
Analog output
ADS129xR: modulation clock for respiration measurement, positive side.
ADS129x: leave floating.
4H
VREFN
Analog input
5A
AVSS
Supply
Analog ground
5B
AVSS
Supply
Analog ground
5C
AVSS
Supply
Analog ground
5D
AVSS
Supply
Analog ground
5E
GPIO4
Digital
input/output
General-purpose input/output pin 4
5F
GPIO1
Digital
input/output
General-purpose input/output pin 1
5G
PWDN
Digital input
Power-down pin; active low
(1)
Right leg drive noninverting input
Analog ground
Reserved for future use; must tie to logic low (DGND).
Negative reference voltage
Connect unused pins to AVDD.
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Pin Function: NFBGA Package (continued)
PIN
TYPE
DESCRIPTION
NO.
NAME
5H
VCAP1
—
6A
AVDD
Supply
Analog supply
6B
AVDD
Supply
Analog supply
Analog supply
Analog bypass capacitor; connect 22-μF capacitor to AVSS
6C
AVDD
Supply
6D
DRDY
Digital output
6E
GPIO3
Digital
input/output
General purpose input/output pin 3
6F
DAISY_IN (2)
Digital input
Daisy-chain input; if not used, short to DGND.
6G
RESET
Digital input
System-reset pin; active low
6H
VCAP2
—
7A
AVDD1
Supply
7B
VCAP3
—
7C
DGND
Supply
Digital ground
7D
DGND
Supply
Digital ground
GPIO2
Digital
input/output
General-purpose input/output pin 2
7F
CS
Digital input
SPI chip select; active low
7G
START
Digital input
Start conversion
7H
DGND
Supply
Digital ground
Analog ground for charge pump
7E
Data ready; active low
Analog bypass capacitor; connect 1-μF capacitor to AVSS
Analog supply for charge pump
Analog bypass capacitor; internally generated AVDD + 1.9 V; connect 1-μF
capacitor to AVSS
8A
AVSS1
Supply
8B
CLKSEL
Digital input
Master clock select
8C
DVDD
Supply
Digital power supply
8D
DVDD
Supply
Digital power supply
8E
DOUT
Digital output
SPI data output
8F
SCLK
Digital input
SPI clock
8G
CLK
Digital
input/output
External Master clock input or internal clock output.
8H
DIN
Digital input
SPI data input
(2)
8
When DAISY_IN is not used, tie to logic 0.
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SBAS459K – JANUARY 2010 – REVISED AUGUST 2015
49 DGND
50 DVDD
51 DGND
52 CLKSEL
53 AVSS1
54 AVDD1
55 VCAP3
56 AVDD
57 AVSS
58 AVSS
59 AVDD
60 RLDREF
61 RLDINV
62 RLDIN
63 RLDOUT
64 WCT
PAG PACKAGE
64-Pin TQFP
Top View
IN6N
5
44
GPIO2
IN6P
6
43
DOUT
IN5N
7
42
GPIO1
IN5P
8
41
DAISY_IN
IN4N
9
40
SCLK
IN4P 10
39
CS
IN3N 11
38
START
IN3P 12
37
CLK
IN2N 13
36
RESET
IN2P 14
35
PWDN
IN1N 15
34
DIN
IN1P 16
33
DGND
Copyright © 2010–2015, Texas Instruments Incorporated
AVSS 32
GPIO3
RESV1 31
45
VCAP2 30
4
NC 29
IN7P
VCAP1 28
GPIO4
NC 27
46
VCAP4 26
3
VREFN 25
IN7N
VREFP 24
DRDY
AVSS 23
47
AVDD 22
2
AVDD 21
IN8P
AVSS 20
DVDD
AVDD 19
48
TESTN_PACE_OUT2 18
1
TESTP_PACE_OUT1 17
IN8N
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Pin Functions: TQFP Package
PIN
TYPE
DESCRIPTION
NO.
NAME
1
IN8N (1)
Analog input
Differential analog negative input 8 (ADS1298)
2
IN8P (1)
Analog input
Differential analog positive input 8 (ADS1298)
3
IN7N
(1)
Analog input
Differential analog negative input 7 (ADS1298)
4
IN7P (1)
Analog input
Differential analog positive input 7 (ADS1298)
5
IN6N (1)
Analog input
Differential analog negative input 6 (ADS1296, ADS1298)
6
IN6P (1)
Analog input
Differential analog positive input 6 (ADS1296, ADS1298)
7
IN5N
(1)
Analog input
Differential analog negative input 5 (ADS1296, ADS1298)
8
IN5P (1)
Analog input
Differential analog positive input 5 (ADS1296, ADS1298)
9
IN4N (1)
Analog input
Differential analog negative input 4
10
IN4P
(1)
Analog input
Differential analog positive input 4
11
IN3N (1)
Analog input
Differential analog negative input 3
12
IN3P (1)
Analog input
Differential analog positive input 3
13
IN2N
(1)
Analog input
Differential analog negative input 2
14
IN2P (1)
Analog input
Differential analog positive input 2
15
IN1N (1)
Analog input
Differential analog negative input 1
16
IN1P (1)
Analog input
Differential analog positive input 1
17
TESTP_PACE_OUT1 (1)
Analog
input/buffer
output
Internal test signal/single-ended buffer output based on register settings
18
TESTN_PACE_OUT2 (1)
Analog
input/output
Internal test signal/single-ended buffer output based on register settings
19
AVDD
Supply
Analog supply
20
AVSS
Supply
Analog ground
21
AVDD
Supply
Analog supply
22
AVDD
Supply
Analog supply
23
AVSS
Supply
Analog ground
24
VREFP
Analog
input/output
Positive reference input/output voltage
25
VREFN
Analog input
Negative reference voltage
26
VCAP4
—
Analog bypass capacitor; connect 1-μF capacitor to AVSS
27
NC
—
No connection, can be connected to AVDD or AVSS with a 10-kΩ resistor
28
VCAP1
—
Analog bypass capacitor; connect 22-μF capacitor to AVSS
29
NC
—
No connection, can be connected to AVDD or AVSS with a 10-kΩ resistor
30
VCAP2
—
Analog bypass capacitor; connect 1-μF capacitor to AVSS
31
RESV1
Digital input
32
AVSS
Supply
Analog ground
33
DGND
Supply
Digital ground
34
DIN
Digital input
SPI data input
35
PWDN
Digital input
Power-down pin; active low
36
RESET
Digital input
System-reset pin; active low
37
CLK
Digital
input/output
External Master clock input or internal clock output.
38
START
Digital input
Start conversion
39
CS
Digital input
SPI chip select; active low
40
SCLK
Digital input
SPI clock
41
DAISY_IN (2)
Digital input
Daisy-chain input; if not used, short to DGND.
(1)
(2)
10
Reserved for future use; must tie to logic low (DGND).
Connect unused pins to AVDD.
When DAISY_IN is not used, tie to logic 0.
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Pin Functions: TQFP Package (continued)
PIN
TYPE
DESCRIPTION
NO.
NAME
42
GPIO1
Digital
input/output
43
DOUT
Digital output
44
GPIO2
Digital
input/output
General-purpose input/output pin 2
45
GPIO3
Digital
input/output
General-purpose input/output pin 3
46
GPIO4
Digital
input/output
General-purpose input/output pin 4
47
DRDY
Digital output
48
DVDD
Supply
Digital power supply
49
DGND
Supply
Digital ground
50
DVDD
Supply
Digital power supply
51
DGND
Supply
Digital ground
52
CLKSEL
Digital input
53
AVSS1
Supply
Analog ground
54
AVDD1
Supply
Analog supply
55
VCAP3
—
56
AVDD
Supply
Analog supply
57
AVSS
Supply
Analog ground
58
AVSS
Supply
Analog ground
59
AVDD
Supply
Analog supply
60
RLDREF
Analog input
Right leg drive noninverting input
61
RLDINV
Analog
input/output
Right leg drive inverting input
62
RLDIN
(1)
Analog input
Right leg drive input to mux
63
RLDOUT
Analog output
Right leg drive output
64
WCT
Analog output
Wilson Central Terminal output
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General-purpose input/output pin 1
SPI data output
Data ready; active low
Master clock select
Analog bypass capacitor; internally generated AVDD + 1.9 V; connect 1-μF
capacitor to AVSS
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7 Specifications
7.1 Absolute Maximum Ratings
over operating free-air temperature range (unless otherwise noted) (1)
MIN
MAX
UNIT
AVDD to AVSS
–0.3
5.5
V
DVDD to DGND
–0.3
3.9
V
AVSS to DGND
–3
0.2
V
VREFP input to AVSS
AVSS – 0.3
AVDD + 0.3
V
Analog input voltage
AVSS – 0.3
AVDD + 0.3
V
Digital input voltage
DGND – 0.3
DVDD + 0.3
V
Digital output voltage
DGND – 0.3
DVDD + 0.3
V
100
mA
Input current (momentary)
Input current (continuous)
10
mA
Junction temperature, TJ
–40
150
°C
Storage temperature, Tstg
–60
150
°C
(1)
Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. These are stress ratings
only, which do not imply functional operation of the device at these or any other conditions beyond those indicated under Recommended
Operating Conditions. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.
7.2 ESD Ratings
VALUE
V(ESD)
(1)
(2)
Electrostatic
discharge
Human body model (HBM), per ANSI/ESDA/JEDEC JS-001, all pins (1)
±2000
Charged device model (CDM), per JEDEC specification JESD22-C101, all pins (2)
±500
UNIT
V
JEDEC document JEP155 states that 500-V HBM allows safe manufacturing with a standard ESD control process.
JEDEC document JEP157 states that 250-V CDM allows safe manufacturing with a standard ESD control process.
7.3 Recommended Operating Conditions
over operating ambient temperature range (unless otherwise noted)
MIN
NOM
MAX
UNIT
POWER SUPPLY
Analog power supply (AVDD – AVSS)
2.7
3
5.25
V
Digital power supply (DVDD)
1.65
1.8
3.6
V
AVDD – DVDD
–2.1
3.6
V
ANALOG INPUTS
Full-scale differential input voltage range (AINP – AINN)
±VREF / Gain
V
See the Input Common-Mode Range
subsection of the PGA Settings and Input
Range section
Common-mode input voltage
VOLTAGE REFERENCE INPUTS
Differential reference voltage
3-V supply VREF = (VREFP – VREFN)
2.5
V
5-V supply VREF = (VREFP – VREFN)
4
V
AVSS
V
AVSS + 2.5
V
Negative input (VREFN)
Positive input (VREFP)
CLOCK INPUT
External clock input frequency
CLKSEL pin = 0
1.94
2.048
2.25
MHz
DIGITAL INPUTS
Input Voltage
DGND
DVDD
V
0
70
°C
–40
85
°C
TEMPERATURE RANGE
Operating temperature range
12
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Industrial grade
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7.4 Thermal Information
ADS129x, ADS129xR
THERMAL METRIC (1)
PAG (TQFP)
ZXG (NFBGA)
64 PINS
64 PINS
UNIT
48
°C/W
RθJA
Junction-to-ambient thermal resistance
35
RθJC(top)
Junction-to-case (top) thermal resistance
31
8
°C/W
RθJB
Junction-to-board thermal resistance
26
25
°C/W
ψJT
Junction-to-top characterization parameter
0.1
0.5
°C/W
ψJB
Junction-to-board characterization parameter
N/A
22
°C/W
(1)
For more information about traditional and new thermal metrics, see the Semiconductor and IC Package Thermal Metrics application
report, SPRA953.
7.5 Electrical Characteristics
Min and max specifications apply for all commercial grade (TA = 0°C to 70°C) devices, and from TA = –40°C to +85°C for
industrial-grade devices. Typical specifications at TA = 25°C. All specifications at DVDD = 1.8 V, AVDD – AVSS = 3 V (1),
VREF = 2.4 V, external fCLK = 2.048 MHz, data rate = 500 SPS, HR mode (2), and gain = 6 (unless otherwise noted).
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
±200
pA
ANALOG INPUTS
Input capacitance
20
TA = 25°C, input = 1.5 V
Input bias current
TA = 0°C to 70°C, input = 1.5 V
±1
TA = –40°C to +85°C, input = 1.5 V
No lead-off
DC input impedance
pF
nA
±1.2
nA
1000
MΩ
Current source lead-off detection
500
MΩ
Pullup resistor lead-off detection
10
MΩ
PGA PERFORMANCE
Gain settings
1, 2, 3, 4, 6, 8, 12
Bandwidth
See Table 5
ADC PERFORMANCE
Resolution
Data rate
Data rates up to 8 kSPS, no missing codes
24
Bits
16-kSPS data rate
19
Bits
32-kSPS data rate
17
Bits
fCLK = 2.048 MHz, HR mode
500
32000
SPS
fCLK = 2.048 MHz, LP mode
250
16000
SPS
DC CHANNEL PERFORMANCE
Input-referred noise
Gain = 6 (3), 10 seconds of data
5
Gain = 6, 256 points, 0.5 seconds of data
4
Gain settings ≠ 6, data rates≠ 500 SPS
Integral nonlinearity (4)
8
ppm
Full-scale with gain = 6, best fit,
ADS129xR channel 1
40
ppm
–20 dBFS with gain = 6, best fit,
ADS129xR channel 1
8
ppm
±500
Offset error drift
µV
2
Gain error
Excluding voltage reference error
Gain drift
Excluding voltage reference drift
Gain match between channels
(4)
μVPP
See Noise Measurements section
Full-scale with gain = 6, best fit
Offset error
(1)
(2)
(3)
μVPP
7
±0.2
µV/°C
±0.5
% of FS
5
ppm/°C
0.3
% of FS
Performance is applicable for 5-V operation as well. Production testing for limits is performed at 3 V.
LP mode = low-power mode.
Noise data measured in a 10-second interval. Test not performed in production. Input-referred noise is calculated with input shorted
(without electrode resistance) over a 10-second interval.
The presence of internal demodulation circuitry on channel 1 causes degradation of INL and THD. The effect is pronounced for full-scale
signals and is less for small ECG-type signals.
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Electrical Characteristics (continued)
Min and max specifications apply for all commercial grade (TA = 0°C to 70°C) devices, and from TA = –40°C to +85°C for
industrial-grade devices. Typical specifications at TA = 25°C. All specifications at DVDD = 1.8 V, AVDD – AVSS = 3 V(1),
VREF = 2.4 V, external fCLK = 2.048 MHz, data rate = 500 SPS, HR mode(2), and gain = 6 (unless otherwise noted).
PARAMETER
TEST CONDITIONS
MIN
TYP
–105
MAX
UNIT
AC CHANNEL PERFORMANCE
CMRR
Common-mode rejection ratio
fCM = 50 Hz, 60 Hz (5)
–115
dB
PSRR
Power-supply rejection ratio
fPS = 50 Hz, 60 Hz
90
dB
Crosstalk
fIN = 50 Hz, 60 Hz
–126
dB
Signal-to-noise ratio
fIN = 10 Hz input, gain = 6
112
dB
10 Hz, –0.5 dBFs
–98
dB
ADS129xR channel 1, 10 Hz, –0.5 dBFs
–70
dB
–100
dB
ADS129xR channel 1, 100 Hz, –0.5 dBFs (6)
–68
dB
ADS129xR channel 1, 100 Hz, –20 dBFs (6)
–86
dB
SNR
THD
Total harmonic distortion (4)
100 Hz, –0.5 dBFs (6)
DIGITAL FILTER
–3-dB bandwidth
Digital filter settling
0.262 fDR
Full setting
Hz
4
Conversions
RIGHT LEG DRIVE (RLD) AMPLIFIER AND PACE AMPLIFIERS
RLD integrated noise
BW = 150 Hz
7
μVRMS
Pace integrated noise
BW = 8 kHz
20
µVRMS
Pace-amplifier crosstalk
Crosstalk between pace amplifiers
60
dB
Gain bandwidth product
50 kΩ || 10 pF load, gain = 1
100
kHz
Slew rate
50 kΩ || 10 pF load, gain = 1
0.25
V/μs
Short circuit to GND (AVDD = 3 V)
270
μA
Short circuit to supply (AVDD = 3 V)
550
μA
Short circuit to GND (AVDD = 5 V)
490
μA
Short circuit to supply (AVDD = 5 V)
810
μA
Peak swing (AVSS + 0.3 V to AVDD + 0.3 V)
at AVDD = 3 V
50
μA
Peak swing (AVSS + 0.3 V to AVDD + 0.3 V)
at AVDD = 5 V
75
μA
Pace and RLD amplifier drive
strength
Pace and RLD current
Pace-amplifier output resistance
Total harmonic distortion
fIN = 100 Hz, gain = 1
Common-mode input range
100
Ω
–70
dB
AVSS + 0.7
AVDD – 0.3
V
Common-mode resistor matching Internal 200-kΩ resistor matching
0.1%
Short-circuit current
±0.25
mA
20
μA
Quiescent power consumption
Either RLD or pace amplifier
WILSON CENTRAL TERMINAL (WCT) AMPLIFIER
Integrated noise
See Table 6
nV/√Hz
Gain bandwidth product
BW = 150 Hz
See Table 6
kHz
Slew rate
See Table 6
V/s
Total harmonic distortion
fIN = 100 Hz
Common-mode input range
Short-circuit current
AVSS + 0.3
Through internal 30-kΩ resistor
Quiescent power consumption
(5)
(6)
14
90
dB
AVDD – 0.3
V
±0.25
mA
See Table 6
μA
CMRR is measured with a common-mode signal of AVSS + 0.3 V to AVDD – 0.3 V. The values indicated are the maximum of the eight
channels.
Harmonics above the second harmonic are attenuated by the digital filter.
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Electrical Characteristics (continued)
Min and max specifications apply for all commercial grade (TA = 0°C to 70°C) devices, and from TA = –40°C to +85°C for
industrial-grade devices. Typical specifications at TA = 25°C. All specifications at DVDD = 1.8 V, AVDD – AVSS = 3 V(1),
VREF = 2.4 V, external fCLK = 2.048 MHz, data rate = 500 SPS, HR mode(2), and gain = 6 (unless otherwise noted).
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
LEAD-OFF DETECT
Frequency
See Table 16 for settings
0, fDR/4
kHz
Current
See Table 16 for settings
6, 12, 18, 24
nA
Current accuracy
±20%
Comparator threshold accuracy
±30
mV
RESPIRATION (ADS129xR ONLY)
Internal source
Frequency
External source
32, 64
32
kHz
64
22.5
90
157.5
kHz
Phase shift
See Table 16 for settings
Degrees
Impedance range
IRESP = 30 μA
Impedance measurement noise
0.05-Hz to 2-Hz brick wall filter, 32-kHz modulation
clock, phase = 112.5, IRESP = 30 μA with 2-kΩ baseline
load, gain = 4
20
mΩPP
Modulator current
internal reference, signal path = 82 kΩ,
baseline = 2.21 kΩ
29
µA
10
kΩ
Register bit CONFIG3.VREF_4V = 0,
AVDD ≥ 2.7 V
2.4
V
Register bit CONFIG3.VREF_4V = 1,
AVDD ≥ 4.4 V
4
V
10
kΩ
EXTERNAL REFERENCE
Input impedance
INTERNAL REFERENCE
Output voltage
VREF accuracy
±0.2%
Internal reference drift
TA = 25°C
35
ppm/°C
Commercial grade, 0°C to 70°C
35
ppm
Industrial grade, –40°C to 85°C
45
ppm
150
ms
Start-up time
SYSTEM MONITORS
Analog-supply reading error
2%
Digital-supply reading error
2%
From power up to DRDY low
Device wakeup
150
ms
9
ms
145
mV
490
μV/°C
STANDBY mode
Temperature-sensor reading,
voltage
TA = 25°C
Temperature-sensor reading,
coefficient
Test-signal frequency
See Table 16 for settings
fCLK / 221, fCLK / 220
Hz
Test-signal voltage
See Table 16 for settings
±1, ±2
mV
Test-signal accuracy
±2%
CLOCK
Internal-oscillator clock
frequency
Nominal frequency
2.048
TA = 25°C
Internal clock accuracy
±0.5%
0°C ≤ TA ≤ 70°C
±2%
–40°C ≤ TA ≤ 85°C, industrial grade versions only
±2.5%
Internal-oscillator start-up time
Internal-oscillator power
consumption
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MHz
20
120
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Electrical Characteristics (continued)
Min and max specifications apply for all commercial grade (TA = 0°C to 70°C) devices, and from TA = –40°C to +85°C for
industrial-grade devices. Typical specifications at TA = 25°C. All specifications at DVDD = 1.8 V, AVDD – AVSS = 3 V(1),
VREF = 2.4 V, external fCLK = 2.048 MHz, data rate = 500 SPS, HR mode(2), and gain = 6 (unless otherwise noted).
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
DIGITAL INPUT/OUTPUT (DVDD = 1.65 V to 3.6 V)
VIH
High-level inpout voltage
VIL
Low-level input voltage
VOH
High-level output voltage
IOH = –500 μA
VOL
Low-level output voltage
IOL = 500 μA
IIN
Input current
0 V < VDigitalInput < DVDD
0.8 DVDD
DVDD + 0.1
V
–0.1
0.2 DVDD
V
DVDD – 0.4
V
–10
0.4
V
10
μA
POWER SUPPLY (RLD, WCT, AND PACE AMPLIFIERS TURNED OFF)
2.75
mA
LP mode (2) (ADS1298)
1.8
mA
HR mode (ADS1298)
3.1
mA
LP mode (ADS1298)
2.1
mA
HR mode (ADS1298)
0.3
mA
LP mode (ADS1298)
0.3
mA
HR mode (ADS1298)
0.5
mA
LP mode (ADS1298)
0.5
ADS1298, ADS1298R,
AVDD – AVSS = 3 V
HR mode
8.8
9.5
mW
LP mode (250 SPS)
6.0
7.0
mW
ADS1296, ADS1296R,
AVDD – AVSS = 3 V
HR mode
7.2
7.9
mW
LP mode (250 SPS)
5.3
6.6
mW
ADS1294, ADS1294R,
AVDD – AVSS = 3 V
HR mode
5.4
6
mW
LP mode (250 SPS)
4.1
4.4
mW
ADS1298, ADS1298R,
AVDD – AVSS = 5 V
HR mode
17.5
mW
LP mode (250 SPS)
12.5
mW
ADS1296, ADS1296R,
AVDD – AVSS = 5 V
HR mode
14.1
mW
10
mW
ADS1294, ADS1294R,
AVDD – AVSS = 5 V
HR mode
10.1
mW
8.3
mW
AVDD – AVSS = 3 V
10
μW
AVDD – AVSS = 5 V
20
μW
AVDD – AVSS = 3 V
2
mW
4
mW
AVDD – AVSS = 3 V
IAVDD
AVDD current
AVDD – AVSS = 5 V
DVDD = 1.8 V
IDVDD
DVDD current
DVDD = 3 V
Power dissipation
Power-down
Standby mode
LP mode (250 SPS)
LP mode (250 SPS)
AVDD – AVSS = 5 V
Quiescent channel power
16
HR mode (ADS1298)
mA
AVDD – AVSS = 3 V, PGA + ADC
818
μW
AVDD – AVSS = 5 V, PGA + ADC
1.5
mW
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7.6 Timing Requirements: Serial Interface
specifications apply from TA = –40°C to +85°C (unless otherwise noted); load on DOUT = 20 pF || 100 kΩ
2.7 V ≤ DVDD ≤ 3.6 V
tCLK
Master clock period
tCSSC
CS low to first SCLK, setup time
tSCLK
1.65 V ≤ DVDD ≤ 2 V
MIN
MAX
MIN
MAX
UNIT
414
514
414
514
ns
6
17
ns
SCLK period
50
66.6
ns
tSPWH, L
SCLK pulse width, high and low
15
25
ns
tDIST
DIN valid to SCLK falling edge: setup time
10
10
ns
tDIHD
Valid DIN after SCLK falling edge: hold time
10
11
ns
tCSH
CS high pulse
2
2
tCLK
tSCCS
Eighth SCLK falling edge to CS high
4
4
tCLK
tSDECODE
Command decode time
4
4
tCLK
tDISCK2ST
DAISY_IN valid to SCLK rising edge: setup time
10
10
ns
tDISCK2HT
DAISY_IN valid after SCLK rising edge: hold time
10
10
ns
7.7 Switching Characteristics: Serial Interface
specifications apply from TA = –40°C to +85°C (unless otherwise noted). Load on DOUT = 20 pF || 100 kΩ.
2.7 V ≤ DVDD ≤ 3.6 V
PARAMETER
MIN
tDOHD
SCLK falling edge to invalid DOUT: hold time
tDOPD
SCLK rising edge to DOUT valid: setup time
tCSDOD
CS low to DOUT driven
tCSDOZ
CS high to DOUT Hi-Z
1.65 V ≤ DVDD ≤ 2 V
MAX
MIN
10
MAX
UNIT
10
ns
17
32
10
20
ns
ns
10
20
ns
tCLK
CLK
tCSSC
tSCLK
SCLK
tCSH
tSDECODE
CS
1
tSPWL
tSPWH
3
2
8
1
tDIHD
tDIST
tSCCS
3
2
8
tDOHD
tDOPD
DIN
tCSDOZ
tCSDOD
Hi-Z
Hi-Z
DOUT
NOTE: SPI settings are CPOL = 0 and CPHA = 1.
Figure 1. Serial Interface Timing
tDISCK2ST
MSBD1
DAISY_IN
SCLK
1
2
tDISCK2HT
LSBD1
3
216
217
218
219
tDOPD
DOUT
LSB
MSB
Don’t Care
MSBD1
NOTE: Daisy-chain timing shown for eight-channel ADS1298 and ADS1298R.
Figure 2. Daisy-Chain Interface Timing
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7.8 Typical Characteristics
at TA = 25°C, AVDD = 3 V, AVSS = 0 V, DVDD = 1.8 V, internal VREFP = 2.4 V, VREFN = AVSS, external clock = 2.048
MHz, data rate = 500 SPS, high-resolution mode, and gain = 6 (unless otherwise noted)
1600
1400
2
1200
1
Occurrences
0
-1
1000
800
600
400
-2
200
Peak-to-Peak Over 10sec = 5mV
9
10
Time (sec)
2.18
0
8
1.68
7
1.17
6
0.67
5
0.17
4
-0.34
3
-0.84
2
-1.35
1
-1.85
0
-2.35
-3
-2.88
Input-Referred Noise (mV)
3
Input-Referred Noise (mV)
Figure 4. Noise Histogram
Figure 3. Input-Referred Noise
2.408
Common-Mode Rejection Ratio (dB)
-130
Internal Reference (V)
2.406
2.404
2.402
2.4
2.398
2.396
-40
35
10
-15
60
-120
-115
-110
-105
-100
-95
Data Rate = 4kSPS
AIN = AVDD - 0.3V to AVSS + 0.3V
-90
-85
85
Gain = 1
Gain = 2
Gain = 3
Gain = 4
Gain = 6
Gain = 8
Gain = 12
-125
10
Figure 5. Internal Reference vs Temperature
0.18
Figure 6. CMRR vs Frequency
1200
AVDD - AVSS = 5V
PGA = 1
1000
0.14
Leakage Current (pA)
Input Leakage Current (nA)
0.16
1k
100
Frequency (Hz)
Temperature (°C)
0.12
0.10
0.08
0.06
0.04
800
600
400
200
0.02
0
0
0.3
0.8
1.3
1.8
2.3
2.8
3.3
3.8
4.3
Input Voltage (V)
Figure 7. Leakage Current vs Input Voltage
18
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4.8
-40
-15
10
35
60
85
Temperature (°C)
Figure 8. Leakage Current vs Temperature
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Typical Characteristics (continued)
at TA = 25°C, AVDD = 3 V, AVSS = 0 V, DVDD = 1.8 V, internal VREFP = 2.4 V, VREFN = AVSS, external clock = 2.048
MHz, data rate = 500 SPS, high-resolution mode, and gain = 6 (unless otherwise noted)
-105
Gain = 2
105
Gain = 8
Total Harmonic Distortion (dB)
Power-Supply Rejection Ratio (dB)
110
Gain = 12
100
95
Gain = 4
Gain = 6
90
Gain = 3
Gain = 2
85
80
Gain = 1
75
-100
Gain = 1
-95
Gain = 3
-90
Gain = 4
-85
Gain = 6
-80
Gain = 8
-75
Data Rate = 4kSPS
AIN = 0.5dBFS
Data Rate = 4kSPS
10
10
1k
100
Frequency (Hz)
Figure 10. THD vs Frequency
8
8
6
Integral Nonlinearity (ppm)
Integral Nonlinearity (ppm)
Figure 9. PSRR vs Frequency
10
6
4
2
0
Gain = 1
Gain = 2
Gain = 3
Gain = 4
Gain = 6
Gain = 8
Gain = 12
-2
-4
-6
-8
-10
-1.0 -0.8 -0.6 -0.4 -0.2
4
2
0
-2
-40°C
-20°C
0°C
+25°C
+40°C
+60°C
-4
-6
-8
0
0.2
0.4
0.6
0.8
-1
1.0
Amplitude (dBFS)
-60
-80
-100
-120
0
-40
-60
-80
-100
-120
-140
-140
-160
-160
0
50
100
150
200
Frequency (Hz)
Figure 13. THD FFT Plot (60-Hz Signal)
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1
250
PGA Gain = 6
THD = -104dB
SNR = 74.5dB
fDR = 32kSPS
-20
Amplitude (dBFS)
PGA Gain = 1
THD = -102dB
SNR = 115dB
fDR = 500SPS
fCLK = External Clock
-40
0.5
Figure 12. INL vs Temperature
Figure 11. INL vs PGA Gain
0
0
-0.5
+70°C
+85°C
Input Range (Normalized to Full-Scale)
Input (Normalized to Full-Scale)
-20
1k
100
Frequency (Hz)
-180
Gain = 12
-70
70
-180
0
2
4
6
8
10
12
14
16
Frequency (kHz)
Figure 14. FFT Plot (60-Hz Signal)
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Typical Characteristics (continued)
at TA = 25°C, AVDD = 3 V, AVSS = 0 V, DVDD = 1.8 V, internal VREFP = 2.4 V, VREFN = AVSS, external clock = 2.048
MHz, data rate = 500 SPS, high-resolution mode, and gain = 6 (unless otherwise noted)
800
70
700
60
Data From 31 Devices, Two Lots
Number of Bins
500
400
300
50
40
30
20
200
10
100
10
12
11
PGA Gain
0.66
9
0.54
8
0.42
7
0.30
6
0.18
5
0.06
4
-0.06
3
-0.18
2
-0.53
1
-0.29
0
0
-0.41
Offset (mV)
600
Error (%)
Figure 16. Test-Signal Amplitude Accuracy
Figure 15. Offset vs PGA Gain (Absolute Value)
80
120
Data From 31 Devices, Two Lots
Current Setting = 24nA
Data From 31 Devices, Two Lots
70
100
Number of Bins
Number of Bins
60
50
40
30
80
60
40
20
20
10
0
30
15.5
20
13.5
10
Power (mW)
Integral Nonlinearity (ppm)
17.5
Channel 1
Channel 2
Channel 3
Channel 4
Channel 5
Channel 6
Channel 7
Channel 8
-20
-30
-40
2.93
2.37
1.80
1.24
0.68
0.12
-0.45
AVDD = 3V
AVDD = 5V
11.5
9.5
7.5
5.5
3.5
1.5
-50
-1
-0.8 -0.6 -0.4 -0.2
0
0.2
0.4
0.6
Input Range (Normalized to Full-Scale)
Figure 19. ADS129xR Nonlinearity
20
Figure 18. Lead-Off Current-Source Accuracy Distribution
40
-10
-1.01
Error in Current Magnitude (nA)
Figure 17. Lead-Off Comparator Threshold Accuracy
0
-1.57
Threshold Error (mV)
-2.14
-2.70
35
30
25
20
15
10
5
0
-10
-15
-20
0
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0.8
1
0
1
2
3
4
5
6
7
8
Number of Channels Disabled
Figure 20. ADS1298 and ADS1298R Channel Power
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Typical Characteristics (continued)
at TA = 25°C, AVDD = 3 V, AVSS = 0 V, DVDD = 1.8 V, internal VREFP = 2.4 V, VREFN = AVSS, external clock = 2.048
MHz, data rate = 500 SPS, high-resolution mode, and gain = 6 (unless otherwise noted)
120
105
Signal-to-Noise Ratio (dB)
Total Harmonic Distortion (dBc)
110
100
95
90
85
80
75
70
110
100
90
80
Internal Master Clock, AVDD = 3V
Internal Master Clock, AVDD = 5V
External Master Clock, AVDD = 3V
External Master Clock, AVDD = 5V
70
60
65
fIN = 10Hz, -0.5dBFS
50
60
1
2
3
4
5
6
7
8
-60
-50
-40
-30
-20
-12
-5
-2
-0.5
Input Amplitude (dBFS)
Channel
Figure 21. ADS129xR THD
Figure 22. SNR vs Input Amplitude
(10-Hz Sine Wave)
2.406
2.404
Vref (V)
2.402
2.400
2.398
2.396
2.394
2.392
±40
±15
10
35
60
85
Temperature (ƒC)
110
C001
Figure 23. Internal VREF Drift vs Temperature
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8 Parameter Measurement Information
8.1 Noise Measurements
NOTE
The ADS129xR channel performance differs from the ADS129x in regards to respiration
circuitry found on channel one. Unless otherwise noted, ADS129x refers to all
specifications and functional descriptions of the ADS1294, ADS1296, ADS1298,
ADS1294R, ADS1296R, and ADS1298R. ADS129xR refers to all specifications and
functional descriptions of only the ADS1294R, ADS1296R, and ADS1298R.
Optimize the ADS129x noise performance by adjusting the data rate and PGA setting. Reduce the data rate to
increase the averaging, and the noise drops correspondingly. Increase the PGA value to reduce the inputreferred noise. This lowered noise level is particularly useful when measuring low-level biopotential signals.
Table 1 and Table 2 summarize the noise performance of the ADS129x in high-resolution (HR) mode and lowpower (LP) mode, respectively, with a 3-V analog power supply. Table 3 and Table 4 summarize the noise
performance of the ADS129x in HR and LP modes, respectively, with a 5-V analog power supply. The data are
representative of typical noise performance at TA = 25°C. The data shown are the result of averaging the
readings from multiple devices and are measured with the inputs shorted together. A minimum of 1000
consecutive readings are used to calculate the RMS and peak-to-peak noise for each reading. For the two
highest data rates, the noise is limited by quantization noise of the ADC and does not have a gaussian
distribution. Thus, the ratio between rms noise and peak-to-peak noise is approximately 10. For the lower data
rates, the ratio is approximately 6.6.
Table 1 to Table 4 show measurements taken with an internal reference. The data are also representative of the
ADS129x noise performance when using a low-noise external reference such as the REF5025.
Table 1. Input-Referred Noise μVRMS (μVPP) in High-Resolution Mode
3-V Analog Supply and 2.4-V Reference (1)
DR BITS OF
CONFIG1
REGISTER
OUTPUT
DATA RATE
(SPS)
–3-dB
BANDWIDTH
(Hz)
PGA
GAIN = 1
PGA
GAIN = 2
PGA
GAIN = 3
000
32000
8398
335 (3553)
168 (1701)
001
16000
4193
56 (613)
28 (295)
010
8000
2096
12.4 (111)
011
4000
1048
100
2000
101
110
(1)
PGA
GAIN = 4
PGA
GAIN = 6
PGA
GAIN = 8
PGA
GAIN = 12
112 (1100)
85 (823)
58 (529)
42.5 (378)
28.6 (248)
18.8 (188)
14.3 (143)
9.7 (94)
7.4 (69)
5.2 (44.3)
6.5 (54)
4.5 (37.9)
3.5 (29.7)
2.6 (21.7)
2.2 (17.8)
1.8 (13.8)
6.1 (44.8)
3.2 (23.3)
2.4 (17.1)
1.9 (14)
1.5 (11.1)
1.3 (9.7)
1.2 (8.5)
524
4.1 (27.8)
2.2 (15.4)
1.6 (11)
1.3 (9.1)
1.1 (7.3)
1 (6.5)
0.9 (6)
1000
262
2.9 (19)
1.6 (10.1)
1.2 (7.5)
1 (6.2)
0.8 (5)
0.7 (4.6)
0.6 (4.1)
500
131
2.1 (12.5)
1.1 (6.8)
0.9 (5.1)
0.7 (4.3)
0.6 (3.5)
0.5 (3.1)
0.5 (2.9)
At least 1000 consecutive readings used to calculate the RMS and peak-to-peak noise values in this table.
Table 2. Input-Referred Noise μVRMS (μVPP) in Low-Power Mode
3-V Analog Supply and 2.4-V Reference (1)
DR BITS OF
CONFIG1
REGISTER
OUTPUT
DATA RATE
(SPS)
–3-dB
BANDWIDTH
(Hz)
PGA
GAIN = 1
PGA
GAIN = 2
PGA
GAIN = 3
000
16000
4193
333 (3481)
166 (1836)
001
8000
2096
56 (554)
28 (272)
010
4000
1048
12.5 (99)
011
2000
524
100
1000
101
500
110
250
(1)
22
PGA
GAIN = 4
PGA
GAIN = 6
PGA
GAIN = 8
PGA
GAIN = 12
111 (1168)
84 (834)
56 (576)
42 (450)
28 (284)
19 (177)
14.3 (133)
9.7 (85)
7.4 (64)
5 (42.4)
6.5 (51)
4.5 (35)
3.4 (25.9)
2.4 (18.8)
2 (14.5)
1.5 (11.3)
6.1 (41.8)
3.2 (22.2)
2.3 (15.9)
1.8 (12.1)
1.4 (9.3)
1.2 (7.8)
1 (6.7)
262
4.1 (26.3)
2.2 (14.6)
1.6 (9.9)
1.3 (8.1)
1 (6.2)
0.8 (5.4)
0.7 (4.7)
131
3 (17.9)
1.6 (9.8)
1.1 (6.8)
0.9 (5.7)
0.7 (4.2)
0.6 (3.6)
0.5 (3.4)
65
2.1 (11.9)
1.1 (6.3)
0.8 (4.6)
0.7 (4)
0.5 (3)
0.5 (2.6)
0.4 (2.4)
At least 1000 consecutive readings used to calculate the RMS and peak-to-peak noise values in this table.
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Table 3. Input-Referred Noise μVRMS (μVPP) in High-Resolution Mode
5-V Analog Supply and 4-V Reference (1)
DR BITS OF
CONFIG1
REGISTER
OUTPUT
DATA RATE
(SPS)
–3-dB
BANDWIDTH
(Hz)
PGA
GAIN = 1
PGA
GAIN = 2
PGA
GAIN = 3
PGA
GAIN = 4
PGA
GAIN = 6
PGA
GAIN = 8
PGA
GAIN = 12
000
32000
8398
521 (5388)
260 (2900)
173 (1946)
130 (1403)
87 (917)
65 (692)
44 (483)
001
16000
4193
86 (1252)
43 (633)
29 (402)
22 (298)
15 (206)
11 (141)
7 (91)
010
8000
2096
17 (207)
9 (112)
6 (71)
4 (57)
3 (36)
3 (29)
2 (18)
011
4000
1048
6.4 (48.2)
3.4 (25.9)
2.417.7)
1.9 (15.4)
1.5 (11.2)
1.3 (9.6)
1.1 (8.2)
100
2000
524
4.2 (29.9)
2.3 (15.9)
1.6 (11.1)
1.3 (9.3)
1 (7.5)
0.9 (6.6)
0.8 (5.8)
101
1000
262
2.9 (18.8)
1.6 (10.4)
1.1 (7.8)
0.9 (6.1)
0.7 (4.9)
0.6 (4.7)
0.6 (3.9)
110
500
131
2 (12.8)
1.1 (7.2)
0.8 (5.2)
0.7 (4)
0.5 (3.3)
0.5 (3.3)
0.4 (2.7)
(1)
At least 1000 consecutive readings used to calculate the RMS and peak-to-peak noise values in this table.
Table 4. Input-Referred Noise μVRMS (μVPP) in Low-Power Mode
5-V Analog Supply and 4-V Reference (1)
DR BITS OF
CONFIG1
REGISTER
OUTPUT
DATA RATE
(SPS)
–3-dB
BANDWIDTH
(Hz)
PGA
GAIN = 1
PGA
GAIN = 2
PGA
GAIN = 3
PGA
GAIN = 4
PGA
GAIN = 6
PGA
GAIN = 8
PGA
GAIN = 12
000
16000
4193
526 (5985)
263 (2953)
175 (1918)
132 (1410)
88 (896)
66 (681)
44 (458)
001
8000
2096
88 (1201)
44 (619)
29 (411)
22 (280)
15 (191)
11 (139)
7 (83)
010
4000
1048
17 (208)
9 (103)
6 (62)
4 (52)
3 (37)
2 (25)
2 (16)
011
2000
524
6 (41.1)
3.3 (23.3)
2.2 (15.5)
1.8 (12.3)
1.3 (9.8)
1.1 (7.8)
0.9 (6.5)
100
1000
262
4.1 (27.1)
2.3 (14.8)
1.5 (10.1)
1.2 (8.1)
0.9 (6)
0.8 (5.4)
0.7 (4.4)
101
500
131
2.9 (17.4)
1.6 (9.6)
1.1 (6.6)
0.9 (5.9)
0.7 (4.3)
0.6 (3.4)
0.5 (3.2)
110
250
65
2.1 (11.9)
1.1 (6.6)
0.8 (4.6)
0.6 (3.7)
0.5 (3)
0.4 (2.5)
0.4 (2.2)
(1)
At least 1000 consecutive readings used to calculate the RMS and peak-to-peak noise values in this table.
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9 Detailed Description
9.1 Overview
NOTE
The ADS129xR channel performance differs from the ADS129x in regards to respiration
circuitry found on channel one. Unless otherwise noted, ADS129x refers to all
specifications and functional descriptions of the ADS1294, ADS1296, ADS1298,
ADS1294R, ADS1296R, and ADS1298R. ADS129xR refers to all specifications and
functional descriptions of only the ADS1294R, ADS1296R, and ADS1298R.
The ADS129x are low-power, multichannel, simultaneously-sampling, 24-bit delta-sigma (ΔΣ) analog-to-digital
converters (ADCs) with integrated programmable gain amplifiers (PGAs). These devices incorporate various
ECG-specific
functions that make them
well-suited for
scalable electrocardiogram
(ECG),
electroencephalography (EEG), and electromyography (EMG) applications. These devices are also used in highperformance, multichannel data acquisition systems by powering down the ECG-specific circuitry.
The ADS129x have a highly-programmable multiplexer (mux) that allows for temperature, supply, input short,
and RLD measurements. Additionally, the mux allows any of the input electrodes to be programmed as the
patient reference drive. The PGA gain is chosen from one of seven settings: 1, 2, 3, 4, 6, 8, or 12. The ADCs in
the device offer data rates from 250 SPS to 32 kSPS. Communicate with the device by using an SPI-compatible
interface. The device provides four GPIO pins for general use. Synchronize multiple devices by using the START
pin.
Program the internal reference to either 2.4 V or 4 V. The internal oscillator generates a 2.048-MHz clock. The
versatile right-leg drive (RLD) block allows for choosing the average of any combination of electrodes to generate
the patient drive signal. Lead-off detection is accomplished either by using a pullup or pulldown resistor, or a
current source or sink. An internal ac lead-off detection feature is also available. These devices support both
hardware pace detection and software pace detection. Use the Wilson central terminal (WCT) block to generate
the WCT point of the standard 12-lead ECG.
Additionally, the ADS129xR provide options for an internal respiration modulator and a demodulator circuit in the
signal path of channel 1.
24
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9.2 Functional Block Diagram
VREFP
AVDD AVDD1
RESP_MODN
Internal Respiration
Modulator
(ADS129xR)
Test Signal
Temperature Sensor Input
Lead-Off Excitation Source
Power-Supply Signal
ADS129xR
ADS129xR
RESP_MODP
RESP_DEMOD_EN
RESP
DEMOD
VREFN
DVDD
Reference
DRDY
IN1P
EMI
Filter
ΔΣ
ADC1
PGA1
IN1N
SPI
IN2P
EMI
Filter
PGA2
ΔΣ
ADC2
EMI
Filter
PGA3
ΔΣ
ADC3
PGA4
ΔΣ
ADC4
PGA5
ΔΣ
ADC5
CS
SCLK
DIN
DOUT
IN2N
IN3P
IN3N
CLKSEL
IN4P
EMI
Filter
IN4N
Oscillator
Control
CLK
MUX
GPIO1
IN5P
ADS1296/6R/8/8R
EMI
Filter
GPIO4/RCLKO
GPIO3/RCLKO
IN5N
GPIO2
IN6P
EMI
Filter
PGA6
ΔΣ
ADC6
EMI
Filter
PGA7
ΔΣ
ADC7
EMI
Filter
PGA8
RESP
CLK
IN6N
PWDN
IN7P
ADS1298/8R
RESET
IN7N
START
IN8P
ΔΣ
ADC8
IN8N
WCT
C
From
Wmuxc
B
From
Wmuxb
A
From
Wmuxa
PACE
Amplifier 2
PACE
Amplifier 1
G = 0.4
RLD
Amplifier
G = 0.4
WCT
AVSS
AVSS1
RLD RLD
IN RE F
RLD
OUT
RL D
INV
PACE
OUT2
PACE
OUT1
DGND
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9.3 Feature Description
This section discusses the details of the ADS129x internal functional elements. The analog blocks are reviewed
first, followed by the digital interface. Blocks implementing ECG-specific functions are covered at the end.
Throughout this document, fCLK denotes the frequency of the signal at the CLK pin, tCLK denotes the period of the
signal at the CLK pin, fDR denotes the output data rate, tDR denotes the time period of the output data, and fMOD
denotes the modulator input sampling frequency.
9.3.1 Analog Functionality
9.3.1.1 EMI Filter
An RC filter at the input acts as an EMI filter on all channels. The –3-dB filter bandwidth is approximately 3 MHz.
9.3.1.2 Analog Input Structure
The analog input of the ADS129x is shown in Figure 24.
AVDD
INxP,
INxN
5kW
10pF
AVSS
Figure 24. Analog Input Protection Circuit
26
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Feature Description (continued)
9.3.1.3 Input Multiplexer
The ADS129x input multiplexers are very flexible and provide many configurable signal-switching options.
Figure 25 shows the multiplexer on a single channel of the device. The device has eight blocks, one for each
channel. TEST_PACE_OUT1, TEST_PACE_OUT2, and RLD_IN are common to all eight blocks. VINP and VINN
are separate for each of the eight blocks. This flexibility allows for significant device and subsystem diagnostics,
calibration, and configuration. Select the switch settings for each channel by writing 1 to the appropriate values to
the CHnSET[2:0] register (see the CHnSET register for details) and the RLD_MEAS bit in the CONFIG3 register
(see the CONFIG3 register for details). More details of the ECG-specific features of the multiplexer are presented
in the Input Multiplexer (Rerouting The Right Leg Drive Signal) subsection of the ECG-Specific Functions section.
ADS129x
MUX
INT_TEST
TESTP_PACE_OUT1
INT_TEST
MUX[2:0] = 101
TestP
TempP
MvddP
(1)
MUX[2:0] = 100
MUX[2:0] = 011
From LoffP
MUX[2:0] = 000
VINP
MUX[2:0] = 110
EMI
Filter
To PgaP
MUX[2:0] = 010 AND
RLD_MEAS
MUX[2:0] = 001 (AVDD + AVSS)
2
MUX[2:0] = 111
MUX[2:0] = 000
VINN
RLDIN
From LoffN
MUX[2:0] = 001
To PgaN
MUX[2:0] = 010 AND
RLD_MEAS
RLD_REF
MvddN
(1)
TempN
MUX[2:0] = 011
MUX[2:0] = 100
MUX[2:0] = 101
TestN
INT_TEST
TESTN_PACE_OUT2
INT_TEST
(1)
MVDD monitor voltage supply depends on channel number; see the Supply Measurements (MVDDP, MVDDN)
section.
Figure 25. Input Multiplexer Block for One Channel
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Feature Description (continued)
9.3.1.3.1 Device Noise Measurements
Setting CHnSET[2:0] = 001 sets the common-mode voltage of (AVDD – AVSS) / 2 to both inputs of the channel.
Use this setting to test the inherent noise of the device.
9.3.1.3.2 Test Signals (TestP and TestN)
Setting CHnSET[2:0] = 101 provides internally-generated test signals for use in subsystem verification at power
up. This functionality allows the entire signal chain to be tested. Although the test signals are similar to the CAL
signals described in the IEC60601-2-51 specification, this feature is not intended for use in compliance testing.
Use register settings to control the test signals (see the CONFIG2: Configuration Register 2 (address = 02h)
(reset = 40h) section for details). The TEST_AMP bit controls the signal amplitude, and the TEST_FREQ bits
control switching at the required frequency.
The test signals are multiplexed and transmitted out of the device at the TESTP_PACE_OUT1 and
TESTN_PACE_OUT2 pins. A bit register (CONFIG2.INT_TEST = 0) deactivates the internal test signals so that
the test signal can be driven externally. This feature allows the calibration of multiple devices with the same
signal. The test signal feature cannot be used in conjunction with the external hardware pace feature (see the
External Hardware Approach section for details).
9.3.1.3.3 Auxiliary Differential Input (TESTP_PACE_OUT1, TESTN_PACE_OUT2)
When hardware pace detection is not used, the TESTP_PACE_OUT1 and TESPN_PACE_OUT2 signals can be
used as a multiplexed differential input channel. These inputs can be multiplexed to any of the eight channels.
The performance of the differential input signal fed through these pins is identical to the normal channel
performance.
9.3.1.3.4 Temperature Sensor (TempP, TempN)
The ADS129x contain an on-chip temperature sensor. This sensor uses two internal diodes with one diode
having a current density 16x that of the other, as shown in Figure 26. The difference in current densities of the
diodes yields a difference in voltage that is proportional to absolute temperature.
Temperature Sensor Monitor
AVDD
1x
2x
To MUX TempP
To MUX TempN
8x
1x
AVSS
Figure 26. Measurement of the Temperature Sensor in the Input
As a result of the low thermal resistance of the package to the printed circuit board (PCB), the internal sensor
tracks the PCB temperature closely. Self-heating of the ADS129x causes a higher reading than the temperature
of the surrounding PCB.
The scale factor of Equation 1 converts the temperature reading to °C. Before using this equation, scale the the
temperature reading code to μV.
Temperature (°C) =
28
Temperature Reading (mV) - 145,300 mV
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490 mV/°C
+ 25°C
(1)
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Feature Description (continued)
9.3.1.3.5 Supply Measurements (MVDDP, MVDDN)
Setting CHnSET[2:0] = 011 sets the channel inputs to different supply voltages of the device.
For channels 1, 2, 5, 6, 7, and 8, (MVDDP – MVDDN) = [0.5 × (AVDD – AVSS)]
For channels 3 and 4, (MVDDP – MVDDN) = DVDD / 4.
To avoid saturating the PGA while measuring power supplies, set the gain to 1.
For example, if AVDD = 2.5 V and AVSS = –2.5 V, then the measurement result is 2.5 V.
9.3.1.3.6 Lead-Off Excitation Signals (LoffP, LoffN)
The lead-off excitation signals are fed into the multiplexer before the switches. The comparators that detect the
lead-off condition are also connected to the multiplexer block before the switches. For a detailed description of
the lead-off block, refer to the Lead-Off Detection section.
9.3.1.3.7 Auxiliary Single-Ended Input
The RLD_IN pin is primarily used for routing the right leg drive (RLD) signal to any of the electrodes in case the
RLD electrode falls off. However, the RLD_IN pin can be used as a multiple single-ended input channel. The
signal at the RLD_IN pin can be measured with respect to the voltage at the RLD_REF pin using any of the eight
channels. This measurement is done by setting the channel multiplexer setting to 010, and the RLD_MEAS bit of
the CONFIG3 register to 1.
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Feature Description (continued)
9.3.1.4 Analog Input
The analog input to the ADS129x is fully differential. Assuming PGA = 1, the differential input (INP – INN) can
span between –VREF to VREF. The absolute range for INP and INN must be between AVSS – 0.3 V and AVDD +
0.3 V. See Table 13 for an explanation of the correlation between the analog input and the digital codes. As
shown in Figure 27 and Figure 28, there are two general methods of driving the analog input of the ADS129x:
single-ended or differential. INP and INN are 180° out-of-phase in the differential input method. When the input is
single-ended, the INN input is held at the common-mode voltage (CM), preferably at midsupply. The INP input
swings around the same common-mode voltage and the peak-to-peak amplitude swings from CM – VREF to CM
+ VREF. When the input is differential, the common-mode is given by (INP + INN) / 2. Both the INP and INN
inputs swing from CM + ½ VREF to CM – ½ VREF. For optimal performance, use the ADS129x devices in a
differential configuration.
±VREF
to
+VREF
Device
VREF
Peak-to-Peak
Device
VREF
Peak-to-Peak
Common
Voltage
Common
Voltage
a) Single-Ended Input
b) Differential Input
Figure 27. Methods of Driving the ADS129x: Single-Ended or Differential
CM + VREF
+VREF
INP
CM Voltage
±VREF
CM ± VREF
INN = CM Voltage
t
Single-Ended Inputs
CM + 1/2 VREF
INP
+VREF
CM Voltage
CM ± 1/2 VREF
INN
±VREF
t
Differential Inputs
Common-Mode Voltage (Differential Mode) =
(INP) + (INN)
, Common-Mode Voltage (Single-Ended Mode) = INN
2
Input Range (Differential Mode) = (AINP ± AINN) = 2 VREF
Figure 28. Using the ADS129x in Single-Ended and Differential Input Modes
30
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9.3.1.5 PGA Settings and Input Range
The PGA is a differential input and differential output amplifier, as shown in Figure 29. The PGA has seven gain
settings (1, 2, 3, 4, 6, 8, and 12) that are set by writing to the CHnSET register (see the CHnSET: Individual
Channel Settings (n = 1 to 8) (address = 05h to 0Ch) (reset = 00h) section). The ADS129x have CMOS inputs,
and therefore have negligible current noise. Table 5 shows the typical values of bandwidths for various gain
settings. Table 5 shows the small-signal bandwidth.
From MuxP
PGAp
R2
50kΩ
R1
20kΩ
(for Gain = 6)
To ADC
R2
50kΩ
PGAn
From MuxN
Figure 29. PGA Implementation
Table 5. PGA Gain versus Small-Signal Bandwidth
GAIN
NOMINAL BANDWIDTH AT ROOM
TEMPERATURE (kHz)
1
237
2
146
3
127
4
96
6
64
8
48
12
32
The resistor string of the PGA that implements the gain has 120 kΩ of resistance for a gain of 6. This resistance
provides a current path across the outputs of the PGA in the presence of a differential input signal. This current
is in addition to the quiescent current specified for the device in the presence of a differential signal at the input.
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9.3.1.5.1 Input Common-Mode Range
The usable input common-mode range of the front end depends on various parameters, including the maximum
differential input signal, supply voltage, PGA gain, and more. This range is described in Equation 2:
æ Gain ´ VMAX _ DIFF ö
æ Gain ´ VMAX _ DIFF ö
AVDD - 0.2 V - çç
÷÷ > CM > AVSS + 0.2 V + çç
÷÷
2
2
è
ø
è
ø
where
•
•
VMAX_DIFF = maximum differential signal at the input of the PGA
CM = common-mode range
(2)
For example, If VDD = 3 V, gain = 6, and VMAX_DIFF = 350 mV, then 1.25 V < CM < 1.75 V.
9.3.1.5.2 Input Differential Dynamic Range
The differential (INP – INN) signal range depends on the analog supply and reference used in the system. This
range is shown in Equation 3.
2VREF
± VREF
Full-Scale Range =
=
Gain
Gain
(3)
The 3-V supply, with a reference of 2.4 V and a gain of 6 for ECGs, is optimized for power with a differential
input signal of approximately 300 mV. For higher dynamic range, use a 5-V supply with a reference of 4 V (set by
the VREF_4V bit of the CONFIG3 register) to increase the differential dynamic range.
9.3.1.5.3 ADC Delta-Sigma Modulator
Power Spectral Density (dB)
Each channel of the ADS129x has a 24-bit, delta-sigma ADC. This converter uses a second-order modulator
optimized for low-power applications. The modulator samples the input signal at the rate of fMOD = fCLK / 4 for
high-resolution (HR) mode and fMOD = fCLK / 8 for low-power (LP) mode. As in the case of any delta-sigma
modulator, the noise of the ADS129x is shaped until fMOD / 2, as shown in Figure 30. Use the on-chip digital
decimation filters, explained in the Digital Decimation Filter section, to filter out the noise at higher frequencies.
These on-chip decimation filters also provide antialias filtering. This feature of the delta-sigma converters
drastically reduces the complexity of the analog antialiasing filters that are typically needed with Nyquist ADCs.
0
−10
−20
−30
−40
−50
−60
−70
−80
−90
−100
−110
−120
−130
−140
−150
−160
0.001
0.01
0.1
Normalized Frequency (fIN/fMOD)
1
G001
Figure 30. Modulator Noise Spectrum up to 0.5 × fMOD
32
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9.3.1.6 Reference
Figure 31 shows a simplified block diagram of the ADS129x internal reference. The reference voltage is
generated with respect to AVSS. When using the internal voltage reference, connect VREFN to AVSS.
22mF
VCAP1
R1
(1)
Bandgap
2.4V or 4V
R3
VREFP
(1)
10mF
R2
(1)
VREFN
AVSS
To ADC Reference Inputs
(1)
For VREF = 2.4 V: R1 = 12.5 kΩ, R2 = 25 kΩ, and R3 = 25 kΩ. For VREF = 4 V: R1 = 10.5 kΩ, R2 = 15 kΩ, and R3 =
35 kΩ.
Figure 31. Internal Reference
The external band-limiting capacitors determine the amount of reference noise contribution. For high-end ECG
systems, choose capacitor values with a bandwidth that is limited to less than 10Hz, so that the reference noise
does not dominate the system noise. When using a 3-V analog supply, set the internal reference to 2.4 V. For a
5-V analog supply, set the internal reference to 4 V by setting the VREF_4V bit in the CONFIG2 register.
Alternatively, the internal reference buffer can be powered down and VREFP can be applied externally. Figure 32
shows a typical external reference drive circuitry. Power down is controlled by the PD_REFBUF bit in the
CONFIG3 register. By default, the device wakes up in external reference mode.
100 k
22 nF
+5 V
0.1 F
10 OPA350
100 5V
VIN
10 F
OUT
10 F
0.1 F
To VREFP
Pin
100 F
REF5025
1 F
TRIM
Figure 32. External Reference Driver
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9.3.1.7 ECG-Specific Functions
9.3.1.7.1 Input Multiplexer (Rerouting The Right Leg Drive Signal)
The input multiplexer has ECG-specific functions for the right leg drive (RLD) signal. The RLD signal is available
at the RLDOUT pin after the appropriate channels are selected for the RLD derivation, feedback elements are
installed external to the chip, and the loop is closed. This signal can be fed after filtering, or fed directly into the
RLDIN pin as shown in Figure 33. Multiplex the RLDIN signal into any one of the input electrodes by setting the
mux bits of the appropriate channel set registers to 110 for P-side or 111 for N-side. Figure 33 shows the RLD
signal generated from channels 1, 2, and 3 routed to the N-side of channel 8. Use this feature to dynamically
change the electrode that is used as the reference signal to drive the patient body. The corresponding channel
cannot be used and can be powered down.
RLD_SENSP[0] = 1
IN1P
EMI
Filter
PGA1
RLD_SENSN[0] = 1
MUX1[2:0] = 000
IN1N
RLD_SENSP[1] = 1
IN2P
EMI
Filter
PGA2
RLD_SENSN[1] = 1
MUX2[2:0] = 000
IN2N
RLD_SENSP[2] = 1
IN3P
EMI
Filter
PGA3
RLD_SENSN[2] = 1
MUX3[2:0] = 000
¼
¼
¼
IN3N
RLD_SENSP[7] = 0
IN8P
EMI
Filter
PGA8
MUX8[2:0] = 111
RLD_SENSN[7] = 0
IN8N
MUX
(AVDD + AVSS)/2
ADS1298
RLDIN
RLDREF_INT
RLDREF_INT
RLDREF
Filter or
Feedthrough
RLD_AMP
RLDOUT
1MW
1.5nF
(1)
RLDINV
(1)
(1)
Typical values for example only.
Figure 33. Example of RLDOUT Signal Configured to be Routed to IN8N
34
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9.3.1.7.2 Input Multiplexer (Measuring The Right Leg Drive Signal)
The RLDOUT signal can also be routed to a channel (that is not used for the calculation of RLD) for
measurement. Figure 34 shows the register settings to route the RLDIN signal to channel 8. The measurement is
done with respect to the voltage on the RLDREF pin. If RLDREF is set to internal, it is at (AVDD + AVSS) / 2.
This feature is useful for debugging purposes during product development.
RLD_SENSP[0] = 1
IN1P
EMI
Filter
PGA1
RLD_SENSN[0] = 1
MUX1[2:0] = 000
IN1N
RLD_SENSP[1] = 1
IN2P
EMI
Filter
PGA2
RLD_SENSN[1] = 1
MUX2[2:0] = 000
IN2N
RLD_SENSP[2] = 1
IN3P
EMI
Filter
PGA3
RLD_SENSN[2] = 1
MUX3[2:0] = 000
¼
¼
¼
IN3N
RLD_SENSP[7] = 0
IN8P
EMI
Filter
PGA8
MUX8[2:0] = 010
RLD_SENSN[7] = 0
IN8N
MUX
RLDREF_INT
(AVDD + AVSS)/2
RLDREF_INT
MUX8[2:0] = 010
AND
RLD_MEAS = 1
RLD_AMP
ADS1298
RLD_IN
RLD_REF
Filter or
Feedthrough
RLD_OUT
1MW
1.5nF
(1)
RLD_INV
(1)
(1)
Typical values for example only.
Figure 34. RLDOUT Signal Configured to be Read Back by Channel 8
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9.3.1.7.3 Wilson Central Terminal (WCT) and Chest Leads
In the standard 12-lead ECG, WCT voltage is defined as the average of right arm (RA), left arm (LA), and left leg
(LL) electrodes. This voltage is used as the reference voltage for the measurement of the chest leads. The
ADS129x has three integrated low-noise amplifiers that generate the WCT voltage. Figure 35 shows the block
diagram of the implementation.
IN1P
IN1N
IN2P
IN2N
IN3P
IN3N
IN4P
IN4N
To Channel
PGAs
8:1 MUX
8:1 MUX
30kΩ
WCT2[2:0]
WCT2[5:3]
WCT1[2:0]
WCTa
8:1 MUX
WCTb
WCTc
30kΩ
30kΩ
WCT
80pF
ADS1294/6/8
AVSS
Figure 35. WCT Voltage
These devices provide the flexibility to route any one of the eight signals (IN1P to IN4N) to each of the amplifiers
to generate the average. This flexibility allows the RA, LA, and LL electrodes to be connected to any input of the
first four channels, depending on the lead configuration.
Each of the three amplifiers in the WCT circuitry can be powered down individually with register settings. By
powering up two amplifiers, the average of any two electrodes is generated at the WCT pin. Powering up one
amplifier provides the buffered electrode voltage at the WCT pin. The WCT amplifiers have limited drive strength,
and thus, should be buffered if used to drive a low-impedance load.
Table 6 shows the typical WCT performance when using any 1, 2, or 3 of the WCT buffers.
Table 6. Typical WCT Performance
36
PARAMETER
ANY ONE
(A, B, or C)
ANY TWO
(A+B, A+C, or B+C)
ALL THREE
(A+B+C)
UNIT
Integrated noise
540
382
312
nVRMS
Power
53
59
65
μW
–3-dB BW
30
59
89
kHz
Slew rate
BW limited
BW limited
BW limited
V/μs
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As shown in Table 6, the overall noise reduces when more than one WCT amplifier is powered up. This noise
reduction is a result of the fact that noise is averaged by the passive summing network at the output of the
amplifiers. Powering down individual buffers gives negligible power savings because a significant portion of the
circuitry is shared between the three amplifiers. The bandwidth of the WCT node is limited by the RC network.
The internal summing network consists of three 30-kΩ resistors and a 80-pF capacitor. For optimal performance,
add an external 100-pF capacitor. The effective bandwidth depends on the number of amplifiers that are
powered up, as shown in Table 6.
Only use the WCT node to drive very high input impedances (typically greater than 500 MΩ). A typical
application connects this WCT signal to the negative inputs of a ADS129x for use as a reference signal for the
chest leads.
As mentioned, all three WCT amplifiers can be connected to one of eight analog input pins. The inputs of the
amplifiers are chopped, and the chop frequency varies with the data rates of the ADS129x. The chop frequency
for the three highest data rates scale 1:1. For example, at a 32-kSPS data rate, the chop frequency is 32 kHz in
HR mode with WCT_CHOP = 0. The chop frequency of the four lower data rates is fixed at 4 kHz. When
WCT_CHOP = 1, the chop frequency is fixed to highest data rate frequency (that is, fMOD / 16), as shown in
Table 7. The chop frequency appears at the output of the WCT amplifiers as a small square wave riding on dc.
The amplitude of the square wave is the offset of the amplifier and is typically 5 mVPP. As a result of out-of-band
chopping, this artifact does not interfere with ECG-related measurements. As a result of the chopping function,
the input current leakage on the pins with the connected WCT amplifiers increases at higher data rates and as
the input common voltage swings closer to 0 V (AVSS), as described in Figure 36.
If the output of a channel connected to the WCT amplifier (for example, the V-lead channels) is connected to one
of the pace amplifiers for external pace detection, the chopping artifact appears at the pace amplifier output.
200
DR = 0.5kSPS, 0.25kSPS
DR = 1kSPS
DR = 2kSPS
DR = 4kSPS
DR = 8kSPS
DR = 16kSPS
DR = 32kSPS
180
160
140
120
100
WCT Input Leakage Current (pA)
WCT Input Leakage Current (pA)
200
80
60
40
20
TA = +25°C
0
0.3
0.8
1.3
1.8
2.3
LP Mode
HR Mode
180
160
140
120
100
80
60
40
20
TA = +25°C
0
0.3
2.8
Input Common-Mode Voltage (V)
0.8
1.3
1.8
2.3
2.8
Input Common-Mode Voltage (V)
Figure 36. WCT Input Leakage Current vs Input Voltage
(WCT_CHOP = 0)
Figure 37. WCT Input Leakage Current vs Input Voltage
(WCT_CHOP = 1)
Table 7. WCT Amplifiers Chop Frequency
CONFIG1.DR[2:0] BIT
CONFIG2.WCT_CHOP = 0
000
fMOD/16
fMOD/16
001
fMOD / 32
fMOD / 16
010
fMOD / 64
fMOD / 16
011
fMOD / 128
fMOD / 16
100
fMOD / 128
fMOD / 16
101
fMOD / 128
fMOD / 16
110
fMOD / 128
fMOD / 16
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CONFIG2.WCT_CHOP = 1
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9.3.1.7.3.1 Augmented Leads
In a typical implementation of the 12-lead ECG with eight channels, the augmented leads are calculated digitally.
In certain applications, it may be required that all leads are derived in analog rather than digital. The ADS1298
and ADS1298R provide the option to generate the augmented leads by routing appropriate averages to channels
5, 6, and 7. The same three amplifiers that are used to generate the WCT signal are also used to generate the
Goldberger central terminal (GCT) signals. Figure 38 shows an example of generating the augmented leads in
analog domain. In this implementation, more than eight channels are used to generate the standard 12 leads.
This feature is not available in the ADS1294, ADS1294R, ADS1296 and ADS1296R.
IN1P
IN1N
IN2P
IN2N
IN3P
IN3N
IN4P
IN4N
To Channel
PGAs
8:1 MUX
WCTb
8:1 MUX
WCT2[2:0]
WCT2[5:3]
WCT1[2:0]
WCTa
8:1 MUX
WCTc
avF_ch4
ADS1298
avF_ch6
avF_ch5
avF_ch7
IN5P
IN5N
IN6P
IN6N
IN7P
IN7N
To Channel
PGAs
Figure 38. Analog Domain Augmented Leads
9.3.1.7.3.2 Right Leg Drive with the WCT Point
In certain applications, the out-of-phase version of the WCT is used as the RLD reference. The ADS1298
provides the option to have a buffered version of the WCT terminal at the RLD_OUT pin. This signal can be
inverted in phase using an external amplifier and then used as the right leg drive. Refer to the Right Leg Drive
(RLD DC Bias Circuit) section for more details.
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9.3.1.7.4 Lead-Off Detection
Patient electrode impedances decay over time; therefore, these electrode connections must be continuously
monitored to verify that a suitable connection is present. The ADS129x lead-off detection functional block
provides significant flexibility to choose from various lead-off detection strategies. Although called lead-off
detection, this feature is in fact electrode-off detection.
The basic principle is to inject an excitation signal and measure the response to determine if the electrode is off.
As shown in the lead-off detection functional block diagram in Figure 39, this circuit provides two different
methods of determining the state of the patient electrode. The methods differ in the frequency content of the
excitation signal. Lead-off can be selectively done on a per channel basis using the LOFF_SENSP and
LOFF_SENSN registers. The internal excitation circuitry can be disabled while the sensing circuitry is enabled.
AVDD
AVSS
FLEAD_OFF[1:0]
Vx
FLEAD_OFF[1:0]
10pF
10pF
7MΩ
7MΩ
(AVDD + AVSS)/2
3.3MΩ
Patient
Skin,
Electrode Contact
Model
Patient
Protection
Resistor
12pF
3.3MΩ
12pF
3.3MΩ
3.3MΩ
3.3MΩ
Anti-Aliasing Filter
< 512kHz
3.3MΩ
47nF
51kΩ
LOFF_STATP
100kΩ
LOFF_SENSP AND
VLEAD_OFF_EN
LOFF_SENSN AND
VLEAD_OFF_EN
VINP
51kΩ
100kΩ
EMI
Filter
LOFF_SENSP AND
VLEAD_OFF_EN
47nF
47nF
51kΩ
VINN
AVDD
PGA
LOFF_SENSN AND
VLEAD_OFF_EN
AVSS
To ADC
LOFF_STATN
4-Bit
DAC
COMP_TH[2:0]
100kΩ
RLD OUT
Figure 39. Lead-Off Detection
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9.3.1.7.4.1 DC Lead-Off
In this approach, the lead-off excitation is accomplished with a dc signal. Choose a dc excitation signal from
either a pullup or pulldown resistor, or from a current source or sink system, as shown in Figure 40. Select by
setting the VLEAD_OFF_EN bit in the LOFF register. One side of the channel is pulled to supply, and the other
side is pulled to ground. Swap the pullup resistor and pulldown resistor by setting the bits in the LOFF_FLIP
register, as shown in Figure 41. If using a current source or sink, set the magnitude of the current by using the
ILEAD_OFF[1:0] bits in the LOFF register. The current source or sink gives larger input impedance compared to
the 10-MΩ pullup or pulldown resistor.
AVDD
AVDD
AVDD
ADS129x
AVDD
ADS129x
ADS129x
ADS129x
10MW
10MW
INP
INP
INP
PGA
INN
10MW
INP
PGA
PGA
INN
INN
PGA
INN
10MW
10MW
a) Pull-Up/Pull-Down Resistors
b) Current Source
Figure 40. DC Lead-Off Excitation Options
a) LOFF_FLIP = 0
10MW
a) LOFF_FLIP = 1
Figure 41. LOFF_FLIP Usage
Response sensing is achieved either by looking at the digital output code from the device, or by monitoring the
input voltages with on-chip comparators. If either of the electrodes is off, the pullup or pulldown resistors saturate
the channel. Look at the output code to determine if either the P-side or the N-side is off. To pinpoint which side
is off, check the comparator outputs. During conversion, the input voltage is simultaneously monitored by using a
comparator and a 4-bit DAC with levels that are set by the COMP_TH[2:0] bits in the LOFF register. The
comparator outputs are stored in the LOFF_STATP and LOFF_STATN registers. These two registers are
available as a part of the output data stream (see the Data Output Pin (DOUT) section). If dc lead-off is not used,
the lead-off comparators can be powered down by setting the PD_LOFF_COMP bit in the CONFIG4 register.
An example procedure to turn on dc lead-off is given in the Lead-Off section.
9.3.1.7.4.2 AC Lead-Off
This method uses an out-of-band ac signal for excitation. The ac signal is generated by providing pullup and
pulldown resistors at the input with a fixed frequency. The ac signal is passed through an antialiasing filter to
prevent aliasing. Select the frequency with the FLEAD_OFF[1:0] bits in the LOFF register. The excitation
frequency is a function of the output data rate and is fDR / 4. This out-of-band excitation signal is passed through
the channel and measured at the output.
AC signal sensing is achieved by passing the signal through the channel to digitize the signal, and measuring the
output. The ac excitation signals are introduced at a frequency that is above the band of interest, generating an
out-of-band differential signal that can be filtered out separately and processed. By measuring the magnitude of
the excitation signal at the output spectrum, the lead-off status is calculated. Therefore, the ac lead-off detection
is accomplished simultaneously with the ECG signal acquisition.
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9.3.1.7.5 RLD Lead-Off
Determine if the RLD electrode is connected in the ADS129x by powering down the RLD amplifier. After power
down, there are two measurement procedures to determine the RLD electrode connect status: a pullup or
pulldown resistor, or a sink or source current source, as shown in Figure 42. Set the reference level of the
comparator to determine the acceptable RLD impedance threshold.
Patient
Skin,
Electrode Contact
Model
Patient
Protection
Resistor
To ADC input (through VREF
connection to any of the channels).
47nF
51kW
RLD_STAT
100kW
RLD_SENS AND
RLD_SENS AND
VLEAD_OFF_EN
VLEAD_OFF_EN
ILGND_OFF[1:0]
AVSS
AVSS
Figure 42. RLD Lead-Off Detection at Power Up
The current source, or pullup or pulldown resistor method has no function when the RLD amplifier is powered on.
Use the comparator to sense the voltage at the output of the RLD amplifier. The comparator threshold is set by
the same LOFF[7:5] bits that are used to set the thresholds for the other negative inputs.
9.3.1.7.6 Right Leg Drive (RLD) DC Bias Circuit
Use the right leg drive (RLD) circuitry to counter the common-mode interference in a ECG system as a result of
power lines and other sources, including fluorescent lights. The RLD circuit senses the common-mode voltage of
a selected set of electrodes and creates a negative feedback loop by driving the body with an inverted commonmode signal. The negative feedback loop restricts the common-mode movement to a narrow range, depending
on the loop gain. Stabilizing the entire loop is specific to the individual system, based on the various poles in the
loop. The ADS129x incorporate muxes that are used to select the channel to the operational amplifier. All the
amplifier terminals are available at the pins, allowing selection of the components for the feedback loop. The
circuit shown in Figure 43 shows the overall functional connectivity for the RLD bias circuit.
Set the reference voltage for the RLD to be generated internally ([AVDD + AVSS] / 2), or provided externally with
a resistive divider. The selection of an internal versus external reference voltage for the RLD loop is defined by
writing the appropriate value to the RLDREF_INT bit in the CONFIG3 register.
If the RLD function is not used, power down the amplifier using the PD_RLD bit (see the CONFIG3:
Configuration Register 3 (address = 03h) (reset = 40h) section for details). This bit is also used in daisy-chain
mode to power down all but one of the RLD amplifiers.
The functionality of the RLDIN pin is explained in the Input Multiplexer section. An example procedure to use the
RLD amplifier is shown in the Right Leg Drive section of the Power-Supply Recommendations.
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From
MUX1P
www.ti.com
RLD1P
220kW
PGA1P
50kW
220kW
RLD2P
PGA2P
20kW
50kW
From
MUX2P
50kW
20kW
220kW
PGA1N
From
MUX1N
RLD1N
From
MUX3P
RLD3P
50kW
220kW
PGA2N
From
MUX2N
RLD2N
220kW
PGA3P
50kW
220kW
RLD4P
PGA4P
20kW
50kW
From
MUX4P
50kW
20kW
220kW
PGA3N
From
MUX3N
RLD3N
From
MUX5P
RLD5P
50kW
220kW
PGA4N
RLD4N
From
MUX4N
RLD6P
From
MUX6P
220kW
PGA5P
50kW
220kW
PGA6P
20kW
50kW
50kW
20kW
220kW
PGA5N
From
MUX5N
RLD5N
From
MUX7P
RLD7P
50kW
220kW
PGA6N
From
MUX6N
RLD6N
220kW
PGA7P
50kW
220kW
RLD8P
PGA8P
20kW
50kW
From
MUX8P
50kW
20kW
220kW
PGA7N
From
MUX7N
RLD7N
PGA8N
RLDINV
(1)
CEXT
1.5nF
RLD8N
(1)
REXT
1MW
RLDOUT
50kW
220kW
RLD
Amp
From
MUX8N
(AVDD + AVSS)/2
RLDREF_INT
RLDREF
RLDREF_INT
(1)
Typical values.
(2)
When CONFIG3 bit RLDREF_INT = 0, the RLDREF_INT switch is closed and the RLDREF_INT switch is open.
When CONFIG3 bit RLDREF_INT = 1, the RLDREF_INT switch is open and the RLDREF_INT switch is closed.
Figure 43. RLD Channel Selection
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9.3.1.7.6.1 WCT as RLD
In certain applications, the RLD is derived as the average of RA, LA, and LL. This level is the same as the WCT
voltage. The WCT amplifier has limited drive strength; therefore, only use the WCT to drive very high
impedances directly. The ADS129x provide an option to internally buffer the WCT signal by setting the
WCT_TO_RLD bit in the CONFIG4 register. Short the RLD_OUT and RLD_INV pins external to the device.
Before the RLD_OUT signal is connected to the RLD electrode, use an external amplifier to invert the phase of
the signal for negative feedback.
ADS129x
RLD_INV
RLD_OUT
RLD
Amp
RLD
(AVDD + AVSS)/2
RLDREF_INT
RLD_REF
From WCT Amplifiers
WCT_TO_RLD
RLD_REF
RLDREF_INT
WCT
Figure 44. Using the WCT as the Right Leg Drive (RLD)
9.3.1.7.6.2 RLD Configuration with Multiple Devices
Figure 45 shows multiple devices connected to an RLD.
RLDIN RLD
REF
VA1-8 VA1-8
RLD
OUT
RLDINV
Device 1
Power-Down
RLDIN RLD
REF
VA1-8 VA1-8
RLD
OUT
RLDINV
To Input MUX
Device 2
To Input MUX
To Input MUX
Device N
Power-Down
VA1-8 VA1-8
RLDIN RLD
REF
RLD
OUT
RLDINV
Figure 45. RLD Connection for Multiple Devices
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9.3.1.7.7 Pace Detect
The ADS129x provide flexibility for pace detection by using either software or external hardware. The software
approach is made possible by providing sampling rates up to 32 kSPS. The external hardware approach is made
possible by bringing out the output of the PGA at two pins: TESTP_PACE_OUT1 and TESTN_PACE_OUT2. If
the WCT amplifier is connected to the signal path, switching noise occurs as a result of chopping; see the Wilson
Central Terminal (WCT) and Chest Leads section for details.
9.3.1.7.7.1 Software Approach
To use the software approach, operate the device at 8 kSPS or more to capture the fastest pulse. Afterwards,
digital signal processing is used to identify the presence of the pacemaker pulse. The software approach gives
the utmost flexibility to program the pace detect threshold on-the-fly (dynamically) using software. This flexibility
is increasingly important as pacemakers evolve over time. Two parameters must be considered while measuring
fast pace pulses:
1. PGA bandwidth: determines the gain setting that can be used; shown in Table 5.
2. Settling time: determines the operating data rate for the device. For a step change in input, the digital
decimation filter takes 3 × tDR to settle.
9.3.1.7.7.2 External Hardware Approach
One of the drawbacks of using the software approach is that all channels on a single device must operate at
higher data rates. For systems where high data rates are a problem, the ADS129x provide the option of
connecting external hardware to the output of the PGA to detect the presence of the pulse. The output of the
pace detection logic is then fed into the device through one of the GPIO pins. The GPIO data are transmitted
through the SPI port and loaded 2 tCLKs before DRDY goes low. Two of the eight channels are selected using
register bits in the PACE register: one from the odd-numbered channels, and the other from the even-numbered
channels. During the differential to single-ended conversion, there is an attenuation of 0.4; therefore, the total
gain in the pace path is equal to (0.4 × PGA_GAIN). The pace output signals are multiplexed with the TESTP
and TESTN signals through the TESTP_PACE_OUT1 and TESTN_PACE_OUT2 pins, respectively. Channel
selection is achieved by setting bits[4:1] of the PACE register. If the pace circuitry is not used, turn off the pace
amplifiers by using the PD_PACE bit in the PACE register.
If the output of a channel connected to the WCT amplifier (for example, the V-lead channels) is connected to one
of the pace amplifiers for external pace detection, chopping artifacts appear at the pace amplifier output. See the
Wilson Central Terminal (WCT) and Chest Leads section for more details.
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PACE[4:3]
PACE[2:1]
From
MUX1P
00
PGA1P
50kΩ
00
PGA2P
20kΩ
From
MUX2P
50kΩ
50kΩ
20kΩ
PGA1N
From
MUX1N
00
From
MUX3P
01
50kΩ
PGA2N
00
From
MUX2N
01
From
MUX4P
PGA3P
50kΩ
PGA4P
20kΩ
50kΩ
50kΩ
20kΩ
PGA3N
From
MUX3N
01
From
MUX5P
10
50kΩ
PGA4N
01
From
MUX4N
10
From
MUX6P
PGA5P
50kΩ
PGA6P
20kΩ
50kΩ
50kΩ
20kΩ
PGA5N
From
MUX5N
10
From
MUX7P
11
50kΩ
PGA6N
From
MUX6N
10
PGA7P
50kΩ
11
PGA8P
20kΩ
From
MUX8P
50kΩ
50kΩ
20kΩ
PGA7N
From
MUX7N
11
50kΩ
(AVDD + AVSS)
PGA8N
2
From
MUX8N
11
200kΩ
500kΩ
PDB_PACE
TESTN_PACE_OUT2
PACE
Amp
500kΩ
GPIO1
(1)
PACE_IN (GPIO1)
200kΩ
(AVDD + AVSS)
2
200kΩ
500kΩ
PDB_PACE
TESTP_PACE_OUT1
PACE
Amp
500kΩ
200kΩ
(1)
GPIO1 can be used as the PACE_IN signal.
Figure 46. Hardware Pace Detection Option
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9.3.1.7.8 Respiration
As shown in Table 8, the ADS129xR provide three options for respiration impedance measurement: external
respiration, internal respiration using on-chip modulation signals, and internal respiration using user-generated
modulation signals. The ADS129x provides only external respiration impedance measurement.
Table 8. Respiration Control
RESP.RESP_CTRL[1]
RESP.RESP_CTRL[0]
0
0
Respiration disabled
ADS129x, ADS129xR
0
1
Generates modulation and demodulation signals for external
respiration circuitry. RESP_CLK signals on GPIO2, GPIO3,
and GPIO4.
ADS129x, ADS129xR
1
0
Respiration measurement using internally-generated
RESP_MOD signals.
1
1
Respiration measurement using user-generated modulation
and blocking signal.
(1)
DESCRIPTION
MODE AVAILABLE
ADS129xR
ADS129xR (1)
Do not set RESP_CTRL[1:0] = 11 if CLKSEL = 1 (internal master clock).
For more information on respiration impedance measurement, see Respiration Rate Measurement Using
Impedance Pneumography, SBAA181.
9.3.1.7.8.1 External Respiration Circuitry (RESP_CTRL = 01b)
With this option, GPIO2, GPIO3, and GPIO4 are automatically configured as outputs. The phase relationship
between the signals is shown in Figure 47. GPIO2 is the exclusive-OR of GPIO3 and GPIO4, as shown in
Figure 48. GPIO3 is the modulation signal, and GPIO4 is the demodulation signal. While using this option, the
general-purpose pin functions of GPIO2, GPIO3, and GPIO4 are not available. The modulation frequency is set
to either 64 kHz or 32 kHz by using the RESP_FREQ[2:0] bits in the CONFIG4 register. The remaining bit
options of RESP_FREQ[2:0] generate square waves on GPIO3 and GPIO4. The exclusive-OR out on GPIO2 is
only available in 64-kHz or 32-kHz. The phase of GPIO4, relative to GPIO3, is set by RESP_PH[2:0] bits in the
RESP register.
Use this option to implement custom respiration impedance circuitry external to the ADS129x.
CLK
(2.048MHz)
(Modulation Clock)
GPIO3
tPHASE
Modulation Clock
GPIO4
(Demodulation Clock)
GPIO4
Respiration
Modulation
Generator
tBLKDLY
(Blocking Signal)
GPIO2
Demodulation Clock
GPIO3
GPIO2
RESP_PH[2:0]
Figure 47. External Respiration (RESP_CTRL = 01b)
Timing
Figure 48. External Respiration (RESP_CTRL = 01b) Block
Diagram
Table 9. Switching Characteristics for Figure 47 (1)
2.7 V ≤ DVDD ≤ 3.6 V
PARAMETER
tPHASE
Respiration phase delay, set by RESP.RESP_PH[2:0]
tBLKDLY
Modulation clock rising edge to XOR signal
(1)
Specifications apply from –40°C to 85°C.
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MIN
TYP
22.5
1.65 V ≤ DVDD ≤ 2 V
MAX
MIN
157.5
22.5
TYP
1
5
MAX
UNIT
157.5
Degrees
ns
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9.3.1.7.8.2 Internal Respiration Circuitry with Internal Clock (RESP_CTRL = 10b, ADS129xR Only)
Figure 49 shows a block diagram of the internal respiration circuitry. The internal modulation and demodulator
circuitry can be selectively used.
The modulation block is controlled by the RESP_MOD_EN bit and the demodulation block is controlled by the
RESP_DEMOD_EN bit. The modulation signal is a square wave of magnitude VREFP – AVSS. Using this
option, the output of the modulation circuitry is available at the RESP_MODP and RESP_MODN pins of the
device. This availability allows custom filtering to be added to the square-wave modulation signal. Using this
option, GPIO2, GPIO3, and GPIO4 can be used for other purposes. The modulation frequency is either 64 kHz
or 32 kHz, as set by the RESP_FREQ[2:0] bits in the CONFIG4 register. The phase of the internal demodulation
signal is set by the RESP_PH[2:0] bits in the RESP register.
When this respiration option is enabled, ADS129xR channel 1 cannot be used to acquire ECG signals. If the RA
and LA leads are intended to measure respiration and ECG signals, wire the two leads into channel 1 for
respiration and channel 2 for ECG signals.
CLK
Demodulation
Clock
Modulation
Block
RESP_CTRL[1:0]
RESP_CTRL[1:0]
Blocking
Mod. Clock
RESP_MODN
Modulation
Clock
Respiration Clock
Generator
RESP_MODP
I/O
GPIO3
I/O
GPIO4
I/O
GPIO2
IN1P
EMI
Filter
MUX
Ch1
PGA
Demodulation
Block
Ch1
ADC
IN1N
Figure 49. Internal Respiration Block Diagram
9.3.1.7.8.3 Internal Respiration Circuitry With User-Generated Signals (RESP_CTRL = 11b, ADS129xR Only)
In this mode GPIO2, GPIO3, and GPIO4 are automatically configured as inputs and cannot be used for other
purposes. The signals must be provided as described in Figure 50. Do not use the internal master clock in this
mode.
(Modulation Clock)
GPIO4
tPHASE
tBLKDLY
GPIO2
(Blocking Signal)
Figure 50. Internal Respiration (RESP_CTRL = 11b) Timing Diagram
Table 10. Swtiching Characteristics for Figure 50
(1)
1.65 V ≤ DVDD ≤ 3.6V
PARAMETER
tPHASE
Respiration phase delay
tBLKDLY
Modulation clock rising edge to XOR signal
(1)
MIN
TYP
0
MAX
157.5
0
UNIT
Degrees
5
ns
Specifications apply from –40°C to 85°C.
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9.3.2 Digital Functionality
9.3.2.1 GPIO Pins (GPIO[4:1])
The ADS129x have a total of four general-purpose digital input/output (GPIO) pins available in normal operation.
The digital I/O pins are individually configurable as either inputs or as outputs through the GPIOC bits of the
GPIO register. The GPIOD bits in the GPIO register control the level of the pins. When reading the GPIOD bits,
the data returned are the logic level of the pins, whether they are programmed as inputs or outputs. When the
GPIO pin is configured as an input, a write to the corresponding GPIOD bit has no effect. When configured as an
output, a write to the GPIOD bit sets the output value.
If configured as inputs, these pins must be driven; do not float these pins. The GPIO pins are set as inputs after
power-on or after a reset. Figure 51 shows the GPIO port structure. If not used, short these pins to DGND.
For example, one configuration is to use GPIO1 as the PACEIN signal, multiplex GPIO2 with RESP_BLK signal,
multiplex GPIO3 with the RESP signal, and multiplex GPIO4 with the RESP_PH signal.
GPIO Data (read)
GPIO Pin
GPIO Data (write)
GPIO Control
Figure 51. GPIO Port Pin
9.3.2.2 Power-Down Pin (PWDN)
When PWDN is pulled low, all on-chip circuitry is powered down. To exit power-down mode, take the PWDN pin
high. Upon exiting from power-down mode, the internal oscillator and the reference require time to wakeup.
During power down, shut down the external clock to save power.
9.3.2.3 Reset (RESET Pin and Reset Command)
There are two methods to reset the ADS129x: pull the RESET pin low, or send the RESET opcode command
(see the RESET: Reset Registers to Default Values section). Take the RESET pin low to force a reset. Make
sure to follow the minimum pulse width timing specifications before taking the RESET pin back high. The RESET
command takes effect on the eighth SCLK falling edge of the opcode command. At reset, 18 tCLK cycles are
required to complete initialization of the configuration registers to the default states and start the conversion
cycle. For more information, see the RESET: Reset Registers to Default Values section. An internal reset is
automatically issued to the digital filter whenever registers CONFIG1 and RESP are set to new values with a
WREG command.
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9.3.2.4 Digital Decimation Filter
The digital filter receives the modulator output and decimates the data stream. By adjusting the amount of
filtering, tradeoffs are made between resolution and data rate: filter more for higher resolution, filter less for
higher data rates. Higher data rates are typically used in ECG applications to implement software pace detection
and ac lead-off detection.
The digital filter on each channel consists of a third-order sinc filter. The decimation ratio on the sinc filters is
adjusted by the DR bits in the CONFIG1 register (see Table 16 for details). This setting is a global setting that
affects all channels; therefore, in these devices, all channels operate at the same data rate.
9.3.2.4.1 Sinc Filter Stage (sinx / x)
The sinc filter is a variable-decimation rate, third-order, low-pass filter. Data are supplied to this section of the
filter from the modulator at the rate of fMOD. The sinc filter attenuates the high-frequency noise of the modulator,
then decimates the data stream into parallel data. The decimation rate affects the overall data rate of the
converter.
Equation 4 shows the scaled Z-domain transfer function of the sinc filter.
½H(z)½ =
3
1 - Z-N
1 - Z-1
(4)
The frequency-domain transfer function of the sinc filter is shown in Equation 5.
3
Npf
fMOD
sin
½H(f)½ =
N ´ sin
pf
fMOD
where
•
N = decimation ratio
(5)
0
0
-20
-0.5
-40
-1
Gain (dB)
Gain (dB)
The sinc filter has notches (or zeroes) that occur at the output data rate multiples. At these frequencies, the filter
has infinite attenuation. Figure 52 shows the frequency response of the sinc filter and Figure 53 shows the rolloff
of the sinc filter. With a step change at input, the filter requires 3 × tDR conversion cycles to settle. After a rising
edge of the START pin or completion of the START command, the filter takes tSETTLE periods to give the first
data output. The settling time of the filters at various data rates are discussed in the Start Mode subsection of the
SPI Interface section. Figure 54 and Figure 55 show the filter transfer function to fMOD / 2 and fMOD / 16,
respectively, at different data rates. Figure 56 shows the transfer function extended out to 4 × fMOD. As shown in
the figures, the passband of the ADS129x repeats itself at every fMOD muiltple. Choose input R-C antialiasing
filters for the system that sufficiently attenuate any interference in frequencies around multiples of fMOD.
-60
-80
-1.5
-2
-100
-2.5
-120
-3
-140
0
0.5
1
1.5
2
2.5
3
3.5
4
4.5
Normalized Frequency (fIN / fDR)
Figure 52. Sinc Filter Frequency Response
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5
0
0.05
0.1
0.15
0.2
0.25
0.3
0.35
Normalized Frequency (fIN / fDR)
Figure 53. Sinc Filter Roll-Off
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0
0
DR[2:0] = 110
DR[2:0] = 110
-20
-20
DR[2:0] = 000
DR[2:0] = 000
-40
Gain (dB)
Gain (dB)
-40
-60
-80
-60
-80
-100
-100
-120
-120
-140
-140
0
0.05 0.10 0.15 0.20 0.25 0.30 0.35 0.40 0.45 0.50
0
0.01
Normalized Frequency (fIN/fMOD)
Figure 54. Transfer Function of On-Chip Decimation Filters
to fMOD / 2
10
0.02
0.03
0.04
0.05
0.06
0.07
Normalized Frequency (fIN/fMOD)
DR[2:0] = 000
Figure 55. Transfer Function of On-Chip Decimation Filters
to fMOD / 16
DR[2:0] = 110
-10
Gain (dB)
-30
-50
-70
-90
-110
-130
0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0
Normalized Frequency (fIN/fMOD)
Figure 56. Transfer Function of On-Chip Decimation Filters
to 4 × fMOD for DR[2:0] = 000 and DR[2:0] = 110
9.3.2.5 Clock
The ADS129x provide two different methods for device clocking: internal and external. Internal clocking is ideally
suited for low-power, battery-powered systems. The internal oscillator is trimmed for accuracy at room
temperature. The accuracy varies over the specified temperature range; see the Electrical Characteristics. Clock
selection is controlled by the CLKSEL pin and the CLK_EN register bit.
Use the CLKSEL pin to select either the internal or external clock. The CLK_EN bit in the CONFIG1 register
enables and disables the oscillator clock to be output in the CLK pin. A truth table for these two pins is shown in
Table 11. Use the CLK_EN bit is when multiple devices are connected in a daisy-chain configuration. During
power down, shut down the external clock to save power.
Table 11. CLKSEL Pin and CLK_EN Bit
50
CLKSEL PIN
CONFIG1.CLK_EN BIT
CLOCK SOURCE
CLK PIN STATUS
0
X
External clock
Input: external clock
1
0
Internal clock oscillator
Tri-state
1
1
Internal clock oscillator
Output: internal clock oscillator
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9.4 Device Functional Modes
9.4.1 Data Acquisition
This section describes the data acquisition process in relation to the START and DRDY pins, settled data, and
data readback.
9.4.1.1 Start Mode
Pull the START pin high for at least 2 tCLK periods, or send the START command to begin conversions. When
the START pin is low, or if the START command has not been sent, the device does not issue a DRDY signal
(conversions are halted).
When using the START opcode to begin conversions, hold the START pin low. The ADS129x feature two modes
to control conversion: continous and single-shot. The mode is selected by SINGLE_SHOT (bit 3 of the CONFIG4
register). In multiple device configurations, the START pin is used to synchronize devices (see the MultipleDevice Configuration section for more details).
9.4.1.1.1 Settling Time
The settling time (tSETTLE) is the time it takes for the converter to output fully-settled data when the START signal
is pulled high.
When the START pin is pulled high, or when the START command is sent, the device ADCs convert the input
signals and DRDY is pulled high. The next falling edge of DRDY indicates that data are ready. Figure 57 shows
the timing diagram and Table 12 shows the settling time for different data rates as a function of tCLK. The settling
time depends on fCLK and the decimation ratio (controlled by the DR[2:0] bits in the CONFIG1 register).
START
§ §
§ §
DIN
START
DRDY
tSETTLE
Figure 57. Settling Time for Initial Conversion
Table 12. Settling Times for Different Data Rates (tSETTLE)
DR[2:0]
SETTLING TIME (tCLK Periods)
HIGH-RESOLUTION MODE
LOW-POWER MODE
000
296
584
001
584
1160
010
1160
2312
011
2312
4616
100
4616
9224
101
9224
18440
110
18440
36872
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When the START pin is held high and there is a step change in the input signal, 3 × tDR conversion cycles are
required for the filter to settle to the new value, as shown in Figure 58. Settled data are available on the fourth
DRDY pulse. This settling time must be considered when trying to measure narrow pace pulses for pace
detection. Data are available to read at each DRDY high-to-low transition, but can be ignored.
START
Input Transient
§
Analog
Input
DRDY
4 x tDR
Figure 58. Settling Time for Input Transient
9.4.1.2 Data Ready Pin (DRDY)
DRDY is an output. When DRDY transitions low, new conversion data are ready. The CS signal has no effect on
the data ready signal. Regardless of the status of the CS signal, a rising edge on SCLK pulls DRDY high. Thus,
when using multiple devices in the SPI bus, gate SCLK with CS. The behavior of DRDY depends on if the device
is in RDATAC mode or if the RDATA command is being used to read data on demand. See the RDATAC: Read
Data Continuous and RDATA: Read Data sections for further details.
When reading data with the RDATA command, the read operation can overlap the occurrence of the next DRDY
without data corruption.
Use the START pin or the START command to place the device either in normal data capture mode or pulse
data capture mode.
Figure 59 shows the relationship among DRDY, DOUT, and SCLK during data retrieval (in the case of an
ADS129x with a selected data rate that gives 24-bit resolution). DOUT latches at the rising edge of SCLK. The
device pulls DRDY high at the first falling edge of SCLK, regardless of whether data are being retrieved from the
device or a command is being sent through the DIN pin. The data starts from the MSB of the status word and
then proceeds to the ADC channel data in sequential order (that is, channel 1, channel 2, ..., channel x).
Channels that are powered down still have a position in the data stream; however, the data are not valid and can
be ignored.
CS
DRDY
SCLK
DOUT
MSB
MSB-1
MSB-2
Figure 59. DRDY with Data Retrieval (CS = 0)
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The DRDY signal is cleared on the first SCLK falling edge, regardless of the state of CS. Even if no data are
clocked out, the DRDY signal is still cleared. Take this condition into consideration if the SPI bus is used to
communicate with other devices on the same bus. Figure 60 shows a timing diagram for this multiplexing.
CS
DRDY
SCLK
Figure 60. DRDY and SCLK Behavior for SPI Bus Multiplexing
9.4.1.3 Data Retrieval
Data retrieval is accomplished in one of two methods:
1. RDATAC: the read data continuous command sets the device mode that reads data continuously without
sending opcodes. See the RDATAC: Read Data Continuous section for more details.
2. RDATA: the read data command reads just one data output from the device. See the RDATA: Read Data
section for more details.
See the SPI Command Definitions section for more details.
The conversion data are read by shifting the data out on DOUT. The MSB of the data on DOUT is clocked out on
the first SCLK rising edge. DRDY returns to high on the first SCLK falling edge. Keep DIN low for the entire read
operation.
9.4.1.3.1 Status Word
The ADS129x data readback is preceded by a status word that provides information on the state of the ADC.
The status word is 24 bits long and contains the values for LOFF_STATP, LOFF_STATN, and part of the GPIO
registers. The content alignment is shown in Figure 61.
LOFF_STATP[7:0]
GPIO[7:4]
LOFF_STATN[7:0]
§ §
0
§
0
§ §
1
§
1
§ §
DOUT
§
SCLK
Figure 61. Status Word Content
9.4.1.3.2 Readback Length
The number of bits in the data output depends on the number of channels and the number of bits per channel.
The data format for each channel data is twos complement and MSB first. For the ADS129x with 32-kSPS and
64-kSPS data rates, the number of data bits is 24 status bits + 16 bits per channel × 8 channels = 152 bits. For
all other data rates, the number of data bits is 24 status bits + 24 bits per channel × 8 channels = 216 bits. When
channels are powered down using the user-register setting, the corresponding channel output is set to 0.
However, the sequence of channel outputs remains the same. The ADS1294 outputs four channels of datam and
the ADS1296 outputs six channels of data.
The ADS129x also provide a multiple-readback feature. Set the DAISY_IN bit in the CONFIG1 register to 1 for
multiple readbacks. Simply provide additional SCLKs to read data multiple times; the MSB data byte repeats
after reading the last byte.
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9.4.1.3.3 Data Format
The ADS129x output 24 bits of data per channel in binary twos complement format, MSB first. The LSB has a
weight of VREF / (223 – 1). A positive full-scale input produces an output code of 7FFFFFh and the negative fullscale input produces an output code of 800000h. The output clips at these codes for signals exceeding full-scale.
Table 13 summarizes the ideal output codes for different input signals. For DR[2:0] = 000 and 001, the device
has only 17 and 19 bits of resolution, respectively. The last seven (in 17-bit mode) or five (in 19-bit mode) bits
can be ignored.
Table 13. Ideal Output Code versus Input Signal (1)
INPUT SIGNAL, VIN
(INxP – INxN)
IDEAL OUTPUT CODE (2)
≥ VREF
7FFFFFh
VREF / (223 – 1)
000001h
0
000000h
23
–VREF / (2
– 1)
≤ –VREF (223 / (223 – 1))
(1)
(2)
FFFFFFh
800000h
Only valid for 24-bit resolution data rates, with gain = 1.
Excludes effects of noise, linearity, offset, and gain error.
9.4.1.4 Single-Shot Mode
Enable single-shot mode by setting the SINGLE_SHOT bit in CONFIG4 register to 1. In single-shot mode, the
ADS129x perform a single conversion when the START pin is taken high, or when the START opcode command
is sent. As seen in Figure 62, when a conversion completes, DRDY goes low and further conversions are
stopped. Regardless of whether the conversion data are read or not, DRDY remains low. To begin a new
conversion, take the START pin low and then back high for at least two tCLKs, or transmit the START opcode
again. When switching from continous conversion mode to single-shot mode, make sure the START signal is
pulsed, or issue a STOP command followed by a START command.
START
tSETTLE
4 / fCLK
Data Updating
4 / fCLK
DRDY
Figure 62. DRDY With No Data Retrieval in Single-Shot Mode
Single-shot conversion mode is provided for applications that require nonstandard or noncontinuous data rates.
Issue a START command or toggle the START pin high to reset the digital filter, effectively dropping the data
rate by a factor of four. This mode leaves the system more susceptible to aliasing effects, thus requiring more
complex analog or digital filtering. Loading on the host processor increases because it must toggle the START
pin or send a START command to initiate a new conversion cycle.
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9.4.1.5 Continuous Conversion Mode
Conversions begin when the START pin is taken high for at least two tCLKs, or when the START opcode
command is sent. As seen in Figure 63, the DRDY output goes high when conversions are started and goes low
when data are ready. Conversions continue indefinitely until the START pin is taken low or the STOP opcode
command is transmitted. When the START pin is pulled low or the stop command is issued, the conversion in
progress is allowed to complete. Figure 64 and Table 14 show the required timing of DRDY to the START pin
and the START and STOP opcode commands when controlling conversions in this mode. To keep the converter
running continuously, permanently tie the START pin high. When switching from single-shot mode to continousconversion mode, pulse the START signal or a issue a STOP command followed by a START command. This
conversion mode is ideal for applications that require a continuous stream of conversions results.
START Pin
or
or
(1)
DIN
(1)
START
Opcode
STOP
Opcode
tDR
tSETTLE
DRDY
(1)
START and STOP opcode commands take effect on the seventh SCLK falling edge.
Figure 63. Continuous Conversion Mode
tSDSU
DRDY and DOUT
tDSHD
START Pin
or
STOP Opcode
(1)
STOP(1)
STOP(1)
START and STOP commands take effect on the seventh SCLK falling edge at the end of the opcode transmission.
Figure 64. START to DRDY Timing
Table 14. Timing Requirements for Figure 64
(1)
MIN
MAX
UNIT
tSDSU
START pin low or STOP opcode to DRDY setup time to halt further conversions
16
tCLK
tDSHD
START pin low or STOP opcode to complete current conversion
16
tCLK
(1)
START and STOP commands take effect on the seventh SCLK falling edge at the end of the opcode transmission.
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9.4.2 Multiple-Device Configuration
The ADS129x provide configuration flexibility when multiple devices are connected in a system. The serial
interface typically requires four signals: DIN, DOUT, SCLK, and CS. With one additional chip select signal per
device, multiple devices can be connected together. The number of signals required to interface n devices is 3 +
n.
Daisy-chain the RLD amplifiers as explained in the RLD Configuration with Multiple Devices section. To use the
internal oscillator in a daisy-chain configuration, set one of the devices as the master for the clock source with
the internal oscillator enabled (CLKSEL pin = 1) and the internal oscillator clock brought out of the device by
setting the CLK_EN register bit to 1. Use this master device clock as the external clock source for the other
devices.
When using multiple devices, synchronize the devices with the START signal. The delay from the START signal
to the DRDY signal is fixed for a fixed data rate (see the Start Mode section for more details on the settling
times). As an example, Figure 65 shows the behavior of two devices when synchronized with the START signal.
There are two configurations used to connect multiple devices with a optimal number of interface pins: cascade
or daisy-chain.
ADS12981
START
CLK
START1
DRDY
DRDY1
CLK
ADS12982
START2
DRDY
DRDY2
CLK
CLK
START
DRDY1
DRDY2
Figure 65. Synchronizing Multiple Converters
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9.4.2.1 Cascade Configuration
Figure 66(a) shows a configuration with two devices cascaded together. One of the devices is an ADS1298
(eight channels) and the other is an ADS1294 (four channels). Together, they create a system with 12 channels.
DOUT, SCLK, and DIN are shared. Each device has its own chip select. When a device is not selected by the
corresponding CS being driven to logic 1, the DOUT of this device is high-impedance. This structure allows the
other device to take control of the DOUT bus. This configuration method is suitable for the majority of
applications.
9.4.2.2 Daisy-Chain Configuration
Enable daisy-chain mode by setting the DAISY_EN bit in the CONFIG1 register. Figure 66(b) shows the daisychain configuration. In this configuration, SCLK, DIN, and CS are shared across multiple devices. Connect the
DOUT pin of the first device to the DAISY_IN pin of the next device, thereby creating a chain. Issue one extra
SCLK between each data set. Note that when using daisy-chain mode, the multiple readback feature is not
available. Short the DAISY_IN pin to digital ground if not used. Figure 2 describes the required timing for the
ADS1298 shown in Figure 67. Data from the ADS1298 appear first on DOUT, followed by a don’t care bit, and
finally by the status and data words from the ADS1294.
START
(1)
CLK
START
CLK
START
INT
DRDY
CS
(1)
START
CLK
GPO0
DRDY
CLK
INT
CS
GPO
GPO1
ADS1298
(Device 1)
SCLK
SCLK
MOSI
ADS1298
(Device 1)
SCLK
DIN
DIN
SCLK
MOSI
DOUT
MISO
DAISY_IN1
DOUT1
MISO
Host Processor
START
Host Processor
DOUT2
DRDY
CLK
CS
SCLK
SCLK
CLK
DIN
ADS1294
(Device 2)
DRDY
CS
START
DIN
ADS1294
(Device 2)
DOUT
DAISY_IN2
b) Daisy-Chain Configuration
a) Cascaded Configuration
(1)
0
To reduce pin count, set the START pin low and use the START opcode command to synchronize and start
conversions.
Figure 66. Multiple Device Configurations
DOUT1
DAISY_IN0
1
SCLK
DOUT
LSB1
MSB1
0
2
3
216
LSB0
MSB0
Data from first device (ADS1298)
219
218
217
XX
MSB1
338
LSB1
Data from second device (ADS1294)
Figure 67. Daisy-Chain Timing for Figure 66(b)
Important reminders when using daisy-chain mode:
1. Issue one extra SCLK between each data set (see Figure 67).
2. All devices are configured to the same register values because CS is shared.
3. Device register readback (RREG) is only valid for device 0 in the daisy chain. Only conversion data can be
read from device 1 to device N, where N is the last device in the chain; register data cannot be read.
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If all devices in the chain operate in the same register setting, DIN can be shared, thereby reducing the SPI
communication signals to four, regardless of the number of devices. However, the individual devices cannot be
programmed; therefore, the RLD driver cannot be shared among the multiple devices. Furthermore, an external
clock must be used.
As shown in Figure 2, the SCLK rising edge shifts data out of the ADS129x on DOUT. The SCLK rising edge is
also used to latch data into the device DAISY_IN pin down the chain. This architecture allows for a faster SCLK
rate speed, but it also makes the interface sensitive to board-level signal delays. The more devices in the chain,
the more challenging it becomes to adhere to setup and hold times. A star-pattern connection of SCLK to all
devices, minimizing length of DOUT, and other PCB layout techniques help. Placing delay circuits such as
buffers between DOUT and DAISY_IN is another way to mitigate this challenge. One other option is to insert a D
flip-flop between DOUT and DAISY_IN clocked on an inverted SCLK. In addition, note that daisy-chain mode
requires some software overhead to recombine data bits spread across byte boundaries.
The maximum number of daisy-chained devices depends on the data rate at which the device is operated. The
maximum number of devices can be estimated with Equation 6:
fSCLK
NDEVICES =
fDR (NBITS)(NCHANNELS) + 24
where
•
•
NBITS = device resolution (depends on data rate)
NCHANNELS = number of channels in the device (4, 6, or 8)
(6)
For example, when the ADS1298 (eight-channel, 24-bit version) is operated at a 2-kSPS data rate with a 4-MHz
fSCLK, up to ten devices can be daisy-chained.
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9.5 Programming
9.5.1 SPI Interface
The SPI-compatible serial interface consists of four signals: CS, SCLK, DIN, and DOUT. The interface reads
conversion data, reads and writes registers, and controls the ADS129x operation. The DRDY output is used as a
status signal to indicate when data are ready. DRDY goes low when new data are available.
9.5.1.1 Chip Select Pin (CS)
Chip select (CS) selects the ADS129x devices for SPI communication. While CS is low, the serial interface is
active. CS must remain low for the entire duration of the serial communication. After the serial communication is
finished, always wait four or more tCLK periods before taking CS high. When CS is taken high, the serial interface
resets, SCLK and DIN are ignored, and DOUT enters a high-impedance state. DRDY asserts when data
conversion is complete, regardless of whether CS is high or low.
While ADS129x is selected, the device attempts to decode and execute commands every eight serial clocks. If
the device ceases to execute serial commands, it is possible extra clock pulses were presented that placed the
serial interface into an unknown state. To reset the serial interface to a known state, take CS high and back low
again.
9.5.1.2 Serial Clock (SCLK)
SCLK is the serial peripheral interface (SPI) serial clock. It is used to shift in commands and shift out data from
the device. The serial clock (SCLK) features a Schmitt-triggered input, and clocks data on the DIN and DOUT
pins into and out of the ADS129x. Even though the input has hysteresis, keep SCLK as clean as possible to
prevent glitches from accidentally forcing a clock event. The absolute maximum limit for SCLK is specified in the
Timing Requirements: Serial Interface table.
While ADS129x is selected (CS = low), the device attempts to decode and execute commands every eight serial
clocks. Therefore, present multiples of eight SCLKs every serial transfer to keep the interface in a normal
operating mode. If the interface ceases to function because of extra serial clocks, reset by toggling CS high and
back low.
For a single device, the minimum speed required for SCLK depends on the number of channels, number of bits
of resolution, and output data rate. For multiple cascaded devices, see the Cascade Configuration section.
Equation 7 shows the calculation for minimum SCLK speed.
tSCLK < (tDR – 4tCLK) / (NBITS × NCHANNELS + 24)
(7)
For example, if the ADS1298 is used at 500-SPS (eight channels, 24-bit resolution), the minimum SCLK speed is
110 kHz.
Retrieve data either by putting the device in RDATAC mode or by issuing a RDATA command for data on
demand. The SCLK rate limitation of Equation 7 also applies to RDATAC. For the RDATA command, the
limitation applies if data must be read between two consecutive DRDY signals. Equation 7 assumes that there
are no other commands issued between data captures.
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Programming (continued)
9.5.1.2.1 SCLK Clocking Methods
As shown in Figure 68, there are two different SCLK clocking methods to satisfy the decode timing specification
shown in Figure 1 for multiple-byte commands.
For SCLK speeds that meet the tSDECODE timing requirement shown in Figure 1, transmit SCLK in a continuous
stream when CS is low. This method is not to be confused with a free-running SCLK, where SCLK operates
when CS is high. Free-running SCLK operation is not supported by this device.
For faster SCLK speeds that do not meet the tSDECODE timing requirement, SCLK is transmitted in 8-bit bursts
with a delay between bursts. The absolute maximum SCLK limit is specified in the Timing Requirements: Serial
Interface table. Figure 68 shows the difference between the two SCLK clocking methods for this device.
CS
Continuous Stream Method
SCLK
CS
Burst Method
SCLK
Figure 68. SCLK Clocking Methods
9.5.1.3 Data Input Pin (DIN)
The data input pin (DIN) is used along with SCLK to communicate with the ADS129x (opcode commands and
register data). The device latches data on DIN on the falling edge of SCLK.
9.5.1.4 Data Output Pin (DOUT)
The data output pin (DOUT) is used with SCLK to read conversion and register data from the ADS129x. Data on
DOUT are shifted out on the rising edge of SCLK. DOUT goes to a high-impedance state when CS is high. In
read data continuous mode (see the SPI Command Definitions section for more details), the DOUT output line
also indicates when new data are available. Use this feature to minimize the number of connections between the
device and the system controller.
Figure 69 shows the data output protocol for ADS1298.
DRDY
CS
SCLK
216 SCLKs
DOUT
STAT
CH1
CH2
CH3
CH4
CH5
CH6
CH7
CH8
24-Bit
24-Bit
24-Bit
24-Bit
24-Bit
24-Bit
24-Bit
24-Bit
24-Bit
DIN
Figure 69. SPI Bus Data Output for the ADS1298 (Eight Channels)
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Programming (continued)
9.5.2 SPI Command Definitions
The ADS129x provide flexible configuration control. The opcode commands, summarized in Table 15, control
and configure the operation of the ADS129x. The opcode commands are stand-alone, except for the register
read and register write operations that require a second command byte plus data. CS can be taken high or held
low between opcode commands, but must stay low for the entire command operation (especially for multibyte
commands). System opcode commands and the RDATA command are decoded by the ADS129x on the seventh
falling edge of SCLK. The register read and write opcodes are decoded on the eighth SCLK falling edge. Be sure
to follow SPI timing requirements when pulling CS high after issuing a command.
Table 15. Opcode Command Definitions
COMMAND
DESCRIPTION
FIRST BYTE
SECOND BYTE
SYSTEM COMMANDS
WAKEUP
Wakeup from standby mode
0000 0010 (02h)
—
STANDBY
Enter standby mode
0000 0100 (04h)
—
RESET
Reset the device
0000 0110 (06h)
—
START
Start/restart (synchronize) conversions
0000 1000 (08h)
—
STOP
Stop conversion
0000 1010 (0Ah)
—
DATA READ COMMANDS
RDATAC
Enable Read Data Continuous mode.
This mode is the default mode at power up. (1)
0001 0000 (10h)
—
SDATAC
Stop Read Data Continuously mode
0001 0001 (11h)
—
RDATA
Read data by command; supports multiple read back.
0001 0010 (12h)
—
REGISTER READ COMMANDS
RREG
WREG
(1)
(2)
Read n nnnn registers starting at address r rrrr
001r rrrr (2xh) (2)
000n nnnn
(2)
Write n nnnn registers starting at address r rrrr
(2)
000n nnnn
(2)
010r rrrr (4xh)
When in RDATAC mode, the RREG command is ignored.
n nnnn = number of registers to be read/written – 1. For example, to read/write three registers, set n nnnn = 0 (0010). r rrrr = starting
register address for read/write opcodes.
9.5.2.1 WAKEUP: Exit Standby Mode
The WAKEUP opcode exits low-power standby mode; see the STANDBY: Enter Standby Mode section. Time is
required when exiting standby mode (see the Electrical Characteristics for details). There are no restrictions on
the SCLK rate for this command; issue this command at any time. Any subsequent command must be sent after
4 tCLK cycles.
9.5.2.2 STANDBY: Enter Standby Mode
The STANDBY opcode command enters low-power standby mode. All parts of the circuit are shut down except
for the reference section. Standby mode power consumption is specified in the Electrical Characteristics. There
are no restrictions on the SCLK rate for this command; issue this command at any time. Send a WAKEUP
command to return device to normal operation. Serial interface is active; therefore, register read and write
commands are permitted while in this mode.
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9.5.2.3 RESET: Reset Registers to Default Values
The RESET command resets the digital filter cycle and returns all register settings to the respective default
values. See the Reset (RESET Pin and Reset Command) section for more details. There are no restrictions on
the SCLK rate for this command; issue this command at any time. 18 tCLK cycles are required to execute the
RESET command. Do not send any commands during this time.
9.5.2.4 START: Start Conversions
This opcode starts data conversions. Tie the START pin low to control conversions by command. If conversions
are in progress this command has no effect. The STOP opcode command is used to stop conversions. If the
START command is immediately followed by a STOP command, there must be a gap of 4 tCLK cycles between
the two commands. When the START opcode is sent to the device, keep the START pin low until the STOP
command is issued. (See the Start Mode subsection of the SPI Interface section for more details.) There are no
restrictions on the SCLK rate for this command and it can be issued any time.
9.5.2.5 STOP: Stop Conversions
The STOP opcode stops conversions. Tie the START pin low to control conversions by command. When the
STOP command is sent, the conversion in progress completes and further conversions are stopped. If
conversions are already stopped, this command has no effect. There are no restrictions on the SCLK rate for this
command; issue this command at any time.
9.5.2.6 RDATAC: Read Data Continuous
The RDATAC opcode enables the output of conversion data on each DRDY without the need to issue
subsequent read data opcodes. This opcode places the conversion data in the output register where it may be
shifted out directly. The read data continuous mode is the default mode of the device and the device defaults to
this mode on power up and reset.
RDATAC mode is cancelled by the stop read data continuous command (SDATAC). If the device is in RDATAC
mode, an SDATAC command must be issued before any other commands can be sent to the device. There is no
restriction on the SCLK rate for this command. However, subsequent data retrieval SCLKs or the SDATAC
opcode command must wait at least 4 tCLK cycles. As shown in Figure 70, the timing for RDATAC illustrates the
keep-out zone of 4 tCLK periods around the DRDY pulse when this command cannot be issued. If no data are
retrieved from the device, DOUT and DRDY behave similarly in this mode. To retrieve data from the device after
RDATAC command is issued, make sure that either the START pin is high or the START command is issued.
Figure 70 shows the recommended way to use the RDATAC command. RDATAC is ideally suited for
applications such as data loggers or recorders, where registers are set once and do not need to be reconfigured.
START
DRDY
CS
SCLK
tUPDATE
RDATAC Opcode
DIN
Hi-Z
DOUT
Status Register + 8-Channel Data (216 Bits)
(1)
Next Data
tUPDATE = 4 / fCLK (where fCLK = 1 / tCLK). Do not read data during this time.
Figure 70. RDATAC Usage
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9.5.2.7 SDATAC: Stop Read Data Continuous
This SDATAC opcode command cancels read data continuous (RDATAC) mode. There is no restriction on the
SCLK rate for this command, but the next command must wait for 4 tCLK cycles.
9.5.2.8 RDATA: Read Data
Issue the RDATA command after DRDY goes low to read the conversion result (in SDATAC mode). There is no
restriction on the SCLK rate for this command, and there is no wait time needed for the subsequent commands
or data retrieval SCLKs. To retrieve data from the device after RDATA command is issued, make sure that either
the START pin is high or the START command is issued. When reading data with the RDATA command, the
read operation can overlap the occurrence of the next DRDY without data corruption. Figure 71 shows the
recommended way to use the RDATA command. RDATA is best suited for ECG- and EEG-type systems, where
register settings must be read or changed often between conversion cycles.
START
DRDY
CS
SCLK
RDATA Opcode
DIN
RDATA Opcode
Hi-Z
DOUT
Status Register+ 8-Channel Data (216 Bits)
Figure 71. RDATA Usage
9.5.2.9 Sending Multibyte Commands
The ADS129x serial interface decodes commands in bytes, and requires 4 tCLK periods to decode and execute.
Therefore, when sending multibyte commands, a 4 tCLK period must separate the end of one byte (or opcode)
and the next.
For example, if CLK is 2.048 MHz, then tSDECODE (4 × tCLK) is 1.96 µs. When SCLK is 16 MHz, the maximum
transfer speed for one byte is 500 ns. This byte transfer time does not meet the tSDECODE specification; therefore,
a delay must be inserted so that the end of the second byte arrives 1.46 µs later. However, if SCLK is 4 MHz,
one byte is transferred in 2 µs. Because this transfer time exceeds the tSDECODE specification, the processor can
send subsequent bytes without delay. In the second scenario, the serial port can be programmed to use multiplebyte transfers instead of the single-byte transfers required to meet the timing of the first scenario .
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9.5.2.10 RREG: Read From Register
The RREG opcode command reads register data. The RREG command is a two-byte opcode followed by the
output of the register data. The first byte contains the command opcode and the register address. The second
byte of the opcode specifies the number of registers to read – 1.
First opcode byte: 001r rrrr, where r rrrr is the starting register address.
Second opcode byte: 000n nnnn, where n nnnn is the number of registers to read – 1.
The 17th SCLK rising edge of the operation clocks out the MSB of the first register, as shown in Figure 72. When
the device is in read data continuous mode, it is necessary to issue a SDATAC command before a RREG
command can be issued. An RREG command can be issued any time. However, because this command is a
multibyte command, there are restrictions on the SCLK rate depending on the way the SCLKs are issued. See
the Serial Clock (SCLK) section for more details. CS must be low for the entire command.
CS
1
9
17
25
SCLK
DIN
OPCODE 1
OPCODE 2
REG DATA
DOUT
REG DATA + 1
Figure 72. RREG Command Example: Read Two Registers Starting from Register 00h (ID Register)
(OPCODE 1 = 0010 0000, OPCODE 2 = 0000 0001)
9.5.2.11 WREG: Write to Register
The WREG opcode command writes register data. The WREG command is a two-byte opcode followed by the
input of the register data. The first byte contains the command opcode and the register address. The second
byte of the opcode specifies the number of registers to write – 1.
First opcode byte: 010r rrrr, where r rrrr is the starting register address.
Second opcode byte: 000n nnnn, where n nnnn is the number of registers to write – 1.
After the opcode bytes, the register data follows (in MSB-first format), as shown in Figure 73. The WREG
command can be issued any time. However, because this command is a multibyte command, there are
restrictions on the SCLK rate depending on the way the SCLKs are issued. See the Serial Clock (SCLK) section
for more details. CS must be low for the entire command.
CS
1
9
17
25
SCLK
DIN
OPCODE 1
OPCODE 2
REG DATA 1
REG DATA 2
DOUT
Figure 73. WREG Command Example: Write Two Registers Starting from 00h (ID Register)
(OPCODE 1 = 0100 0000, OPCODE 2 = 0000 0001)
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9.6 Register Maps
Table 16 lists the various ADS129x registers.
Table 16. Register Assignments
ADDRESS
RESET
VALUE
(Hex)
REGISTER
BIT 7
BIT 6
BIT 5
BIT 4
BIT 3
BIT 2
BIT 1
BIT 0
DEV_ID7
DEV_ID6
DEV_ID5
1
0
DEV_ID2
DEV_ID1
DEV_ID0
DEVICE SETTINGS (READ-ONLY REGISTERS)
00h
ID
xx
GLOBAL SETTINGS ACROSS CHANNELS
01h
CONFIG1
06
HR
DAISY_EN
CLK_EN
0
0
DR2
DR1
DR0
02h
CONFIG2
40
0
0
WCT_CHOP
INT_TEST
0
TEST_AMP
TEST_FREQ1
TEST_FREQ0
03h
CONFIG3
40
PD_REFBUF
1
VREF_4V
RLD_MEAS
RLDREF_INT
PD_RLD
RLD_LOFF_
SENS
RLD_STAT
04h
LOFF
00
COMP_TH2
COMP_TH1
COMP_TH0
VLEAD_OFF_
EN
ILEAD_OFF1
ILEAD_OFF0
FLEAD_OFF1
FLEAD_OFF0
CHANNEL-SPECIFIC SETTINGS
05h
CH1SET
00
PD1
GAIN12
GAIN11
GAIN10
0
MUX12
MUX11
MUX10
06h
CH2SET
00
PD2
GAIN22
GAIN21
GAIN20
0
MUX22
MUX21
MUX20
07h
CH3SET
00
PD3
GAIN32
GAIN31
GAIN30
0
MUX32
MUX31
MUX30
08h
CH4SET
00
PD4
GAIN42
GAIN41
GAIN40
0
MUX42
MUX41
MUX40
09h
CH5SET
(1)
00
PD5
GAIN52
GAIN51
GAIN50
0
MUX52
MUX51
MUX50
0Ah
CH6SET
(1)
00
PD6
GAIN62
GAIN61
GAIN60
0
MUX62
MUX61
MUX60
0Bh
CH7SET
(1)
00
PD7
GAIN72
GAIN71
GAIN70
0
MUX72
MUX71
MUX70
0Ch
CH8SET
(1)
00
PD8
GAIN82
GAIN81
GAIN80
0
MUX82
MUX81
MUX80
0Dh
RLD_SENSP
(2)
00
RLD8P (1)
RLD7P (1)
RLD6P (1)
RLD5P (1)
RLD4P
RLD3P
RLD2P
RLD1P
0Eh
RLD_SENSN
(2)
00
RLD8N (1)
RLD7N (1)
RLD6N (1)
RLD5N (1)
RLD4N
RLD3N
RLD2N
RLD1N
0Fh
LOFF_SENSP
(2)
00
LOFF8P
LOFF7P
LOFF6P
LOFF5P
LOFF4P
LOFF3P
LOFF2P
LOFF1P
10h
LOFF_SENSN
(2)
00
LOFF8N
LOFF7N
LOFF6N
LOFF5N
LOFF4N
LOFF3N
LOFF2N
LOFF1N
11h
LOFF_FLIP
00
LOFF_FLIP8
LOFF_FLIP7
LOFF_FLIP6
LOFF_FLIP5
LOFF_FLIP4
LOFF_FLIP3
LOFF_FLIP2
LOFF_FLIP1
LEAD-OFF STATUS REGISTERS (READ-ONLY REGISTERS)
12h
LOFF_STATP
00
IN8P_OFF
IN7P_OFF
IN6P_OFF
IN5P_OFF
IN4P_OFF
IN3P_OFF
IN2P_OFF
IN1P_OFF
13h
LOFF_STATN
00
IN8N_OFF
IN7N_OFF
IN6N_OFF
IN5N_OFF
IN4N_OFF
IN3N_OFF
IN2N_OFF
IN1N_OFF
GPIO AND OTHER REGISTERS
(1)
(2)
14h
GPIO
0F
GPIOD4
GPIOD3
GPIOD2
GPIOD1
GPIOC4
GPIOC3
GPIOC2
GPIOC1
15h
PACE
00
0
0
0
PACEE1
PACEE0
PACEO1
PACEO0
PD_PACE
16h
RESP
00
RESP_
DEMOD_EN1
RESP_MOD_
EN1
1
RESP_PH2
RESP_PH1
RESP_PH0
RESP_CTRL1
RESP_CTRL0
17h
CONFIG4
00
RESP_FREQ2
RESP_FREQ1
RESP_FREQ0
0
SINGLE_
SHOT
WCT_TO_
RLD
PD_LOFF_
COMP
0
18h
WCT1
00
aVF_CH6
aVL_CH5
aVR_CH7
avR_CH4
PD_WCTA
WCTA2
WCTA1
WCTA0
19h
WCT2
00
PD_WCTC
PD_WCTB
WCTB2
WCTB1
WCTB0
WCTC2
WCTC1
WCTC0
CH5SET and CH6SET are not available for the ADS1294 and ADS1294R. CH7SET and CH8SET registers are not available for the
ADS1294, ADS1294R, ADS1296, and ADS1296R.
The RLD_SENSP, PACE_SENSP, LOFF_SENSP, LOFF_SENSN, and LOFF_FLIP registers bits[5:4] are not available for the ADS1294
and ADS1294R. Bits[7:6] are not available for the ADS1294, ADS1296, ADS1294R, and ADS1296R.
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9.6.1 Register Descriptions
The read-only ID control register is programmed during device manufacture to indicate device characteristics.
9.6.1.1 ID: ID Control Register (address = 00h) (reset = xxh)
Figure 74. ID Control Register
7
6
DEV_ID[7:5]
R-x
5
4
1
3
0
2
R-2h
1
DEV_ID[2:0]
R-x
0
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset
Table 17. ID Control Register Field Descriptions
66
Bit
Field
Type
Reset
Description
7:5
DEV_ID[7:5]
R
xh
Device ID
These bits indicate the device family.
000 = Reserved
011 = Reserved
100 = ADS129x device family
101 = Reserved
110 = ADS129xR device family
111 = Reserved
4:3
RESERVED
R
2h
Reserved
Always read back 2h
2:0
DEV_ID[2:0]
R
xh
Channel ID
These bits indicates number of channels.
000 = 4-channel ADS1294 or ADS1294R
001 = 6-channel ADS1296 or ADS1296R
010 = 8-channel ADS1298 or ADS1298R
011 = Reserved
111 = Reserved
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9.6.1.2 CONFIG1: Configuration Register 1 (address = 01h) (reset = 06h)
Figure 75. CONFIG1: Configuration Register 1
7
HR
R/W-0h
6
DAISY_EN
R/W-0h
5
CLK_EN
R/W-0h
4
0
3
0
2
1
DR[2:0]
R/W-6h
R/W-0h
0
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset
Table 18. Configuration Register 1 Field Descriptions
Bit
(1)
Field
Type
Reset
Description
7
HR
R/W
0h
High-resolution or low-power mode
This bit determines whether the device runs in low-power or
high-resolution mode.
0 = LP mode
1 = HR mode
6
DAISY_EN
R/W
0h
Daisy-chain or multiple readback mode
This bit determines which mode is enabled.
0 = Daisy-chain mode
1 = Multiple readback mode
5
CLK_EN
R/W
0h
CLK connection (1)
This bit determines if the internal oscillator signal is connected to
the CLK pin when the CLKSEL pin = 1.
0 = Oscillator clock output disabled
1 = Oscillator clock output enabled
4:3
RESERVED
R/W
0h
Reserved
Always write 0h
2:0
DR[2:0]
R/W
6h
Output data rate
For High-Resolution mode, fMOD = fCLK / 4. For low power mode,
fMOD = fCLK / 8.
These bits determine the output data rate of the device.
000: fMOD / 16 (HR Mode: 32 kSPS, LP Mode: 16 kSPS)
001: fMOD / 32 (HR Mode: 16 kSPS, LP Mode: 8 kSPS)
010: fMOD / 64 (HR Mode: 8 kSPS, LP Mode: 4 kSPS)
011: fMOD / 128 (HR Mode: 4 kSPS, LP Mode: 2 kSPS)
100: fMOD / 256 (HR Mode: 2 kSPS, LP Mode: 1 kSPS)
101: fMOD / 512 (HR Mode: 1 kSPS, LP Mode: 500 SPS)
110: fMOD / 1024 (HR Mode: 500 SPS, LP Mode: 250 SPS)
111: Reserved (do not use)
Additional power is consumed when driving external devices.
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9.6.1.3 CONFIG2: Configuration Register 2 (address = 02h) (reset = 40h)
Configuration register 2 configures the test signal generation. See the Input Multiplexer section for more details.
Figure 76. CONFIG2: Configuration Register 2
7
0
6
0
R/W-1h
5
WCT_CHOP
R/W-0h
4
INT_TEST
R/W-0h
3
0
R/W-0h
2
TEST_AMP
R/W-0h
1
0
TEST_FREQ[1:0]
R/W-0h
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset
Table 19. Configuration Register 2 Field Descriptions
Bit
Field
Type
Reset
Description
7:6
RESERVED
R/W
1h
Reserved
Always write 0h
5
WCT_CHOP
R/W
0h
WCT chopping scheme
This bit determines whether the chopping frequency of WCT
amplifiers is variable or fixed.
0 = Chopping frequency varies, see Table 7
1 = Chopping frequency constant at fMOD / 16
4
INT_TEST
R/W
0h
TEST source
This bit determines the source for the test signal.
0 = Test signals are driven externally
1 = Test signals are generated internally
3
RESERVED
R/W
0h
Reserved
Always write 0h
2
TEST_AMP
R/W
0h
Test signal amplitude
These bits determine the calibration signal amplitude.
0 = 1 × –(VREFP – VREFN) / 2400 V
1 = 2 × –(VREFP – VREFN) / 2400 V
TEST_FREQ[1:0]
R/W
0h
Test signal frequency
These bits determine the calibration signal frequency.
00 = Pulsed at fCLK / 221
01 = Pulsed at fCLK / 220
10 = Not used
11 = At dc
1:0
68
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9.6.1.4 CONFIG3: Configuration Register 3 (address = 03h) (reset = 40h)
Configuration register 3 configures multireference and RLD operation.
Figure 77. CONFIG3: Configuration Register 3
7
PD_REFBUF
6
1
5
VREF_4V
4
RLD_MEAS
3
RLDREF_INT
2
PD_RLD
R/W-0h
R/W-1h
R/W-0h
R/W-0h
R/W-0h
R/W-0h
1
RLD_LOFF_SE
NS
R/W-0h
0
RLD_STAT
R-0h
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset
Table 20. Configuration Register 3 Field Descriptions
Bit
Field
Type
Reset
Description
7
PD_REFBUF
R/W
0h
Power-down reference buffer
This bit determines the power-down reference buffer state.
0 = Power-down internal reference buffer
1 = Enable internal reference buffer
6
RESERVED
R/W
1h
Reserved
Always write 1h
5
VREF_4V
R/W
0h
Reference voltage
This bit determines the reference voltage, VREFP.
0 = VREFP is set to 2.4 V
1 = VREFP is set to 4 V (use only with a 5-V analog supply)
4
RLD_MEAS
R/W
0h
RLD measurement
This bit enables RLD measurement. The RLD signal may be
measured with any channel.
0 = Open
1 = RLD_IN signal is routed to the channel that has the
MUX_Setting 010 (VREF)
3
RLDREF_INT
R/W
0h
RLDREF signal
This bit determines the RLDREF signal source.
0 = RLDREF signal fed externally
1 = RLDREF signal (AVDD – AVSS) / 2 generated internally
2
PD_RLD
R/W
0h
RLD buffer power
This bit determines the RLD buffer power state.
0 = RLD buffer is powered down
1 = RLD buffer is enabled
1
RLD_LOFF_SENS
R/W
0h
RLD sense function
This bit enables the RLD sense function.
0 = RLD sense is disabled
1 = RLD sense is enabled
0
RLD_STAT
R
0h
RLD lead-off status
This bit determines the RLD status.
0 = RLD is connected
1 = RLD is not connected
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9.6.1.5 LOFF: Lead-Off Control Register (address = 04h) (reset = 00h)
The lead-off control register configures the lead-off detection operation.
Figure 78. LOFF: Lead-Off Control Register
7
6
COMP_TH2[2:0]
R/W-0h
5
4
VLEAD_OFF_E
N
R/W-0h
3
2
ILEAD_OFF[1:0]
1
0
FLEAD_OFF[1:0]
R/W-0h
R/W-0h
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset
Table 21. Lead-Off Control Register Field Descriptions
70
Bit
Field
Type
Reset
Description
7:5
COMP_TH[2:0]
R/W
0h
Lead-off comparator threshold
Comparator positive side
000 = 95%
001 = 92.5%
010 = 90%
011 = 87.5%
100 = 85%
101 = 80%
110 = 75%
111 = 70%
Comparator negative side
000 = 5%
001 = 7.5%
010 = 10%
011 = 12.5%
100 = 15%
101 = 20%
110 = 25%
111 = 30%
4
VLEAD_OFF_EN
R/W
0h
Lead-off detection mode
This bit determines the lead-off detection mode.
0 = Current source mode lead-off
1 = pullup or pulldown resistor mode lead-off
3:2
ILEAD_OFF[1:0]
R/W
0h
Lead-off current magnitude
These bits determine the magnitude of current for the current
lead-off mode.
00 = 6 nA
01 = 12 nA
10 = 18 nA
11 = 24 nA
1:0
FLEAD_OFF[1:0]
R/W
0h
Lead-off frequency
These bits determine the frequency of lead-off detect for each
channel.
00 = When any bits of the LOFF_SENSP or LOFF_SENSN
registers are turned on, make sure that FLEAD[1:0] are either
set to 01 or 11
01 = AC lead-off detection at fDR / 4
10 = Do not use
11 = DC lead-off detection turned on
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9.6.1.6 CHnSET: Individual Channel Settings (n = 1 to 8) (address = 05h to 0Ch) (reset = 00h)
The CH[1:8]SET control register configures the power mode, PGA gain, and multiplexer settings channels. See
the Input Multiplexer section for details. CH[2:8]SET are similar to CH1SET, corresponding to the respective
channels.
Figure 79. CHnSET: Individual Channel Settings Register
7
PDn
R/W-0h
6
5
GAINn[2:0]
R/W-0h
4
3
0
R/W-0h
2
1
MUXn[2:0]
R/W-0h
0
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset
Table 22. Individual Channel Settings (n = 1 to 8) Field Descriptions
Bit
Field
Type
Reset
Description
7
PDn
R/W
0h
Power-down
This bit determines the channel power mode for the
corresponding channel.
0 = Normal operation
1 = Channel power-down.
When powering down a channel, TI recommends that the
channel be set to input short by setting the appropriate
MUXn[2:0] = 001 of the CHnSET register.
6:4
GAINn[2:0]
R/W
0h
PGA gain
These bits determine the PGA gain setting.
000 = 6
001 = 1
010 = 2
011 = 3
100 = 4
101 = 8
110 = 12
3
RESERVED
R/W
0h
Reserved
Always write 0h
MUXn[2:0]
R/W
0h
Channel input
These bits determine the channel input selection.
000 = Normal electrode input
001 = Input shorted (for offset or noise measurements)
010 = Used in conjunction with RLD_MEAS bit for RLD
measurements. See the Right Leg Drive (RLD) DC Bias Circuit
subsection of the ECG-Specific Functions section for more
details.
011 = MVDD for supply measurement
100 = Temperature sensor
101 = Test signal
110 = RLD_DRP (positive electrode is the driver)
111 = RLD_DRN (negative electrode is the driver)
2:0
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9.6.1.7 RLD_SENSP: RLD Positive Signal Derivation Register (address = 0Dh) (reset = 00h)
This register controls the selection of the positive signals from each channel for right leg drive (RLD) derivation.
See the Right Leg Drive (RLD) DC Bias Circuit section for details.
Registers bits[5:4] are not available for the ADS1294 or ADS1294R. Bits[7:6] are not available for the ADS1294,
ADS1294R, ADS1296, or ADS1296R.
Figure 80. RLD_SENSP: RLD Positive Signal Derivation Register
7
RLD8P
R/W-0h
6
RLD7P
R/W-0h
5
RLD6P
R/W-0h
4
RLD5P
R/W-0h
3
RLD4P
R/W-0h
2
RLD3P
R/W-0h
1
RLD2P
R/W-0h
0
RLD1P
R/W-0h
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset
Table 23. RLD Positive Signal Derivation Field Descriptions
Bit
72
Field
Type
Reset
Description
7
RLD8P
R/W
0h
IN8P to RLD
Route channel 8 positive signal into RLD derivation
0: Disabled
1: Enabled
6
RLD7P
R/W
0h
IN7P to RLD
Route channel 7 positive signal into RLD derivation
0: Disabled
1: Enabled
5
RLD6P
R/W
0h
IN6P to RLD
Route channel 6 positive signal into RLD derivation
0: Disabled
1: Enabled
4
RLD5P
R/W
0h
IN5P to RLD
Route channel 5 positive signal into RLD derivation
0: Disabled
1: Enabled
3
RLD4P
R/W
0h
IN4P to RLD
Route channel 4 positive signal into RLD derivation
0: Disabled
1: Enabled
2
RLD3P
R/W
0h
IN3P to RLD
Route channel 3 positive signal into RLD derivation
0: Disabled
1: Enabled
1
RLD2P
R/W
0h
IN2P to RLD
Route channel 2 positive signal into RLD channel
0: Disabled
1: Enabled
0
RLD1P
R/W
0h
IN1P to RLD
Route channel 1 positive signal into RLD channel
0: Disabled
1: Enabled
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9.6.1.8 RLD_SENSN: RLD Negative Signal Derivation Register (address = 0Eh) (reset = 00h)
This register controls the selection of the negative signals from each channel for right leg drive derivation. See
the Right Leg Drive (RLD) DC Bias Circuit section for details.
Registers bits[5:4] are not available for the ADS1294 and ADS1294R. Bits[7:6] are not available for the
ADS1294, ADS1294R, ADS1296, or ADS1296R.
Figure 81. RLD_SENSN: RLD Negative Signal Derivation Register
7
RLD8N
R/W-0h
6
RLD7N
R/W-0h
5
RLD6N
R/W-0h
4
RLD5N
R/W-0h
3
RLD4N
R/W-0h
2
RLD3N
R/W-0h
1
RLD2N
R/W-0h
0
RLD1N
R/W-0h
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset
Table 24. RLD Negative Signal Derivation Field Descriptions
Bit
Field
Type
Reset
Description
7
RLD8N
R/W
0h
IN8N to RLD
Route channel 8 negative signal into RLD derivation
0: Disabled
1: Enabled
6
RLD7N
R/W
0h
IN7N to RLD
Route channel 7 negative signal into RLD derivation
0: Disabled
1: Enabled
5
RLD6N
R/W
0h
IN6N to RLD
Route channel 6 negative signal into RLD derivation
0: Disabled
1: Enabled
4
RLD5N
R/W
0h
IN5N to RLD
Route channel 5 negative signal into RLD derivation
0: Disabled
1: Enabled
3
RLD4N
R/W
0h
IN4N to RLD
Route channel 4 negative signal into RLD derivation
0: Disabled
1: Enabled
2
RLD3N
R/W
0h
IN3N to RLD
Route channel 3 negative signal into RLD derivation
0: Disabled
1: Enabled
1
RLD2N
R/W
0h
IN2N to RLD
Route channel 2 negative signal into RLD derivation
0: Disabled
1: Enabled
0
RLD1N
R/W
0h
IN1N to RLD
Route channel 1 negative signal into RLD derivation
0: Disabled
1: Enabled
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9.6.1.9 LOFF_SENSP: Positive Signal Lead-Off Detection Register (address = 0Fh) (reset = 00h)
This register selects the positive side from each channel for lead-off detection. See the Lead-Off Detection
section for details. The LOFF_STATP register bits are only valid if the corresponding LOFF_SENSP bits are set
to 1.
Registers bits[5:4] are not available for the ADS1294 or ADS1294R. Bits[7:6] are not available for the ADS1294,
ADS1294R, ADS1296, or ADS1296R.
Figure 82. LOFF_SENSP: Positive Signal Lead-Off Detection Register
7
LOFF8P
R/W-0h
6
LOFF7P
R/W-0h
5
LOFF6P
R/W-0h
4
LOFF5P
R/W-0h
3
LOFF4P
R/W-0h
2
LOFF3P
R/W-0h
1
LOFF2P
R/W-0h
0
LOFF1P
R/W-0h
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset
Table 25. Positive Signal Lead-Off Detection Field Descriptions
Bit
74
Field
Type
Reset
Description
7
LOFF8P
R/W
0h
IN8P lead off
Enable lead-off detection on IN8P
0: Disabled
1: Enabled
6
LOFF7P
R/W
0h
IN7P lead off
Enable lead-off detection on IN7P
0: Disabled
1: Enabled
5
LOFF6P
R/W
0h
IN6P lead off
Enable lead-off detection on IN6P
0: Disabled
1: Enabled
4
LOFF5P
R/W
0h
IN5P lead off
Enable lead-off detection on IN5P
0: Disabled
1: Enabled
3
LOFF4P
R/W
0h
IN4P lead off
Enable lead-off detection on IN4P
0: Disabled
1: Enabled
2
LOFF3P
R/W
0h
IN3P lead off
Enable lead-off detection on IN3P
0: Disabled
1: Enabled
1
LOFF2P
R/W
0h
IN2P lead off
Enable lead-off detection on IN2P
0: Disabled
1: Enabled
0
LOFF1P
R/W
0h
IN1P lead off
Enable lead-off detection on IN1P
0: Disabled
1: Enabled
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9.6.1.10 LOFF_SENSN: Negative Signal Lead-Off Detection Register (address = 10h) (reset = 00h)
This register selects the negative side from each channel for lead-off detection. See the Lead-Off Detection
section for details. The LOFF_STATN register bits are only valid if the corresponding LOFF_SENSN bits are set
to 1.
Registers bits[5:4] are not available for the ADS1294 or ADS1294R. Bits[7:6] are not available for the ADS1294,
ADS1294R, ADS1296, or ADS1296R.
Figure 83. LOFF_SENSN: Negative Signal Lead-Off Detection Register
7
LOFF8N
R/W-0h
6
LOFF7N
R/W-0h
5
LOFF6N
R/W-0h
4
LOFF5N
R/W-0h
3
LOFF4N
R/W-0h
2
LOFF3N
R/W-0h
1
LOFF2N
R/W-0h
0
LOFF1N
R/W-0h
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset
Table 26. Negative Signal Lead-Off Detection Field Descriptions
Bit
Field
Type
Reset
Description
7
LOFF8N
R/W
0h
IN8N lead off
Enable lead-off detection on IN8N
0: Disabled
1: Enabled
6
LOFF7N
R/W
0h
IN7N lead off
Enable lead-off detection on IN7N
0: Disabled
1: Enabled
5
LOFF6N
R/W
0h
IN6N lead off
Enable lead-off detection on IN6N
0: Disabled
1: Enabled
4
LOFF5N
R/W
0h
IN5N lead off
Enable lead-off detection on IN5N
0: Disabled
1: Enabled
3
LOFF4N
R/W
0h
IN4N lead off
Enable lead-off detectionn on IN4N
0: Disabled
1: Enabled
2
LOFF3N
R/W
0h
IN3N lead off
Enable lead-off detectionion on IN3N
0: Disabled
1: Enabled
1
LOFF2N
R/W
0h
IN2N lead off
Enable lead-off detectionction on IN2N
0: Disabled
1: Enabled
0
LOFF1N
R/W
0h
IN1N lead off
Enable lead-off detectionction on IN1N
0: Disabled
1: Enabled
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9.6.1.11 LOFF_FLIP: Lead-Off Flip Register (address = 11h) (reset = 00h)
This register controls the direction of the current used for lead-off derivation. See the Lead-Off Detection section
for details.
Figure 84. LOFF_FLIP: Lead-Off Flip Register
7
LOFF_FLIP8
R/W-0h
6
LOFF_FLIP7
R/W-0h
5
LOFF_FLIP6
R/W-0h
4
LOFF_FLIP5
R/W-0h
3
LOFF_FLIP4
R/W-0h
2
LOFF_FLIP3
R/W-0h
1
LOFF_FLIP2
R/W-0h
0
LOFF_FLIP1
R/W-0h
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset
Table 27. Lead-Off Flip Register Field Descriptions
Bit
76
Field
Type
Reset
Description
7
LOFF_FLIP8
R/W
0h
Channel 8 LOFF polarity flip
Flip the pullup/pulldown polarity of the current source or resistor
on channel 8 for lead-off derivation.
0: No Flip: IN8P is pulled to AVDD and IN8N pulled to AVSS
1: Flipped: IN8P is pulled to AVSS and IN8N pulled to AVDD
6
LOFF_FLIP7
R/W
0h
Channel 7 LOFF polarity flip
Flip the pullup/pulldown polarity of the current source or resistor
on channel 7 for lead-off derivation.
0: No Flip: IN7P is pulled to AVDD and IN7N pulled to AVSS
1: Flipped: IN7P is pulled to AVSS and IN7N pulled to AVDD
5
LOFF_FLIP6
R/W
0h
Channel 6 LOFF polarity flip
Flip the pullup/pulldown polarity of the current source or resistor
on channel 6 for lead-off derivation.
0: No Flip: IN6P is pulled to AVDD and IN6N pulled to AVSS
1: Flipped: IN6P is pulled to AVSS and IN6N pulled to AVDD
4
LOFF_FLIP5
R/W
0h
Channel 5 LOFF polarity flip
Flip the pullup/pulldown polarity of the current source or resistor
on channel 5 for lead-off derivation.
0: No Flip: IN5P is pulled to AVDD and IN5N pulled to AVSS
1: Flipped: IN5P is pulled to AVSS and IN5N pulled to AVDD
3
LOFF_FLIP4
R/W
0h
Channel 4 LOFF polarity flip
Flip the pullup/pulldown polarity of the current source or resistor
on channel 4 for lead-off derivation.
0: No Flip: IN4P is pulled to AVDD and IN4N pulled to AVSS
1: Flipped: IN4P is pulled to AVSS and IN4N pulled to AVDD
2
LOFF_FLIP3
R/W
0h
Channel 3 LOFF polarity flip
Flip the pullup/pulldown polarity of the current source or resistor
on channel 3 for lead-off derivation.
0: No Flip: IN3P is pulled to AVDD and IN3N pulled to AVSS
1: Flipped: IN3P is pulled to AVSS and IN3N pulled to AVDD
1
LOFF_FLIP2
R/W
0h
Channel 2 LOFF Polarity Flip
Flip the pullup/pulldown polarity of the current source or resistor
on channel 2 for lead-off derivation.
0: No Flip: IN2P is pulled to AVDD and IN2N pulled to AVSS
1: Flipped: IN2P is pulled to AVSS and IN2N pulled to AVDD
0
LOFF_FLIP1
R/W
0h
Channel 1 LOFF Polarity Flip
Flip the pullup/pulldown polarity of the current source or resistor
on channel 1 for lead-off derivation.
0: No Flip: IN1P is pulled to AVDD and IN1N pulled to AVSS
1: Flipped: IN1P is pulled to AVSS and IN1N pulled to AVDD
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9.6.1.12 LOFF_STATP: Lead-Off Positive Signal Status Register (address = 12h) (reset = 00h)
This register stores the status of whether the positive electrode on each channel is on or off. See the Lead-Off
Detection section for details. Ignore the LOFF_STATP values if the corresponding LOFF_SENSP bits are not set
to 1.
When the LOFF_SENSEP bits are 0, the LOFF_STATP bits should be ignored.
Figure 85. LOFF_STATP: Lead-Off Positive Signal Status Register (Read-Only)
7
IN8P_OFF
R-0h
6
IN7P_OFF
R-0h
5
IN6P_OFF
R-0h
4
IN5P_OFF
R-0h
3
IN4P_OFF
R-0h
2
IN3P_OFF
R-0h
1
IN2P_OFF
R-0h
0
IN1P_OFF
R-0h
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset
Table 28. Lead-Off Positive Signal Status Field Descriptions
Bit
Field
Type
Reset
Description
7
IN8P_OFF
R
0h
Channel 8 positive channel lead-off status
Status of whether IN8P electrode is on or off
0: Electrode is on
1: Electrode is off
6
IN7P_OFF
R
0h
Channel 7 positive channel lead-off status
Status of whether IN7P electrode is on or off
0: Electrode is on
1: Electrode is off
5
IN6P_OFF
R
0h
Channel 6 positive channel lead-off status
Status of whether IN6P electrode is on or off
0: Electrode is on
1: Electrode is off
4
IN5P_OFF
R
0h
Channel 5 positive channel lead-off status
Status of whether IN5P electrode is on or off
0: Electrode is on
1: Electrode is off
3
IN4P_OFF
R
0h
Channel 4 positive channel lead-off status
Status of whether IN4P electrode is on or off
0: Electrode is on
1: Electrode is off
2
IN3P_OFF
R
0h
Channel 3 positive channel lead-off status
Status of whether IN3P electrode is on or off
0: Electrode is on
1: Electrode is off
1
IN2P_OFF
R
0h
Channel 2 positive channel lead-off status
Status of whether IN2P electrode is on or off
0: Electrode is on
1: Electrode is off
0
IN1P_OFF
R
0h
Channel 1 positive channel lead-off status
Status of whether IN1P electrode is on or off
0: Electrode is on
1: Electrode is off
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9.6.1.13 LOFF_STATN: Lead-Off Negative Signal Status Register (address = 13h) (reset = 00h)
This register stores the status of whether the negative electrode on each channel is on or off. See the Lead-Off
Detection section for details. Ignore the LOFF_STATN values if the corresponding LOFF_SENSN bits are not set
to 1.
When the LOFF_SENSEN bits are 0, the LOFF_STATP bits should be ignored.
Figure 86. LOFF_STATN: Lead-Off Negative Signal Status Register (Read-Only)
7
IN8N_OFF
R-0h
6
IN7N_OFF
R-0h
5
IN6N_OFF
R-0h
4
IN5N_OFF
R-0h
3
IN4N_OFF
R-0h
2
IN3N_OFF
R-0h
1
IN2N_OFF
R-0h
0
IN1N_OFF
R-0h
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset
Table 29. Lead-Off Negative Signal Status Field Descriptions
Bit
78
Field
Type
Reset
Description
7
IN8N_OFF
R
0h
Channel 8 negative channel lead-off status
Status of whether IN8N electrode is on or off
0: Electrode is on
1: Electrode is off
6
IN7N_OFF
R
0h
Channel 7 negative channel lead-off status
Status of whether IN7N electrode is on or off
0: Electrode is on
1: Electrode is off
5
IN6N_OFF
R
0h
Channel 6 negative channel lead-off status
Status of whether IN6N electrode is on or off
0: Electrode is on
1: Electrode is off
4
IN5N_OFF
R
0h
Channel 5 negative channel lead-off status
Status of whether IN5N electrode is on or off
0: Electrode is on
1: Electrode is off
3
IN4N_OFF
R
0h
Channel 4 negative channel lead-off status
Status of whether IN4N electrode is on or off
0: Electrode is on
1: Electrode is off
2
IN3N_OFF
R
0h
Channel 3 negative channel lead-off status
Status of whether IN3N electrode is on or off
0: Electrode is on
1: Electrode is off
1
IN2N_OFF
R
0h
Channel 2 negative channel lead-off status
Status of whether IN2N electrode is on or off
0: Electrode is on
1: Electrode is off
0
IN1N_OFF
R
0h
Channel 1 negative channel lead-off status
Status of whether IN1N electrode is on or off
0: Electrode is on
1: Electrode is off
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9.6.1.14 GPIO: General-Purpose I/O Register (address = 14h) (reset = 0Fh)
The general-purpose I/O register controls the action of the three GPIO pins. When RESP_CTRL[1:0] is in mode
01 and 11, the GPIO2, GPIO3, and GPIO4 pins are not available for use.
Figure 87. GPIO: General-Purpose I/O Register
7
6
5
4
3
2
GPIOD[4:1]
R/W-0h
1
0
GPIOC[4:1]
R/W-Fh
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset
Table 30. General-Purpose I/O Field Descriptions
Bit
Field
Type
Reset
Description
7:4
GPIOD[4:1]
R/W
0h
GPIO data
These bits are used to read and write data to the GPIO ports.
When reading the register, the data returned correspond to the
state of the GPIO external pins, whether they are programmed
as inputs or as outputs. As outputs, a write to the GPIOD sets
the output value. As inputs, a write to the GPIOD has no effect.
GPIO is not available in certain respiration modes.
3:0
GPIOC[4:1]
R/W
Fh
GPIO control (corresponding GPIOD)
These bits determine if the corresponding GPIOD pin is an input
or output.
0 = Output
1 = Input
9.6.1.15 PACE: Pace Detect Register (address = 15h) (reset = 00h)
This register provides the pace controls that configure the channel signal used to feed the external pace detect
circuitry. See the Pace Detect section for details.
Figure 88. PACE: Pace Detect Register
7
0
R/W-0h
6
0
R/W-0h
5
0
R/W-0h
4
3
PACEE[1:0]
R/W-0h
2
1
PACEO[1:0]
R/W-0h
0
PD_PACE
R/W-0h
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset
Table 31. (For example, CONTROL_REVISION Register) Field Descriptions
Bit
Field
Type
Reset
Description
7:5
RESERVED
R/W
0h
Reserved
Always write 0h
4:3
PACEE[1:0]
R/W
0h
Pace even channels
These bits control the selection of the even number channels
available on TEST_PACE_OUT1. Only one channel may be
selected at any time.
00 = Channel 2
01 = Channel 4
10 = Channel 6 (ADS1296, ADS1296R, ADS1298, ADS1298R)
11 = Channel 8 (ADS1298 and ADS1298R)
2:1
PACEO[1:0]
R/W
0h
Pace odd channels
These bits control the selection of the odd number channels
available on TEST_PACE_OUT2. Only one channel may be
selected at any time.
00 = Channel 1
01 = Channel 3
10 = Channel 5 (ADS1296, ADS1296R, ADS1298, ADS1298R)
11 = Channel 7 (ADS1298, ADS1298R)
PD_PACE
R/W
0h
Pace detect buffer
This bit is used to enable/disable the pace detect buffer.
0 = Pace detect buffer turned off
1 = Pace detect buffer turned on
0
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9.6.1.16 RESP: Respiration Control Register (address = 16h) (reset = 00h)
This register provides the controls for the respiration circuitry; see the Respiration section for details.
Figure 89. RESP: Respiration Control Register
7
RESP_ DEMOD_EN1
R/W-0h
6
RESP_MOD_ EN1
R/W-0h
5
1
R/W-0h
4
3
RESP_PH[2:0]
R/W-0h
2
1
0
RESP_CTRL[1:0]
R/W-0h
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset
Table 32. Respiration Control Register Field Descriptions
Bit
(1)
80
Field
Type
Reset
Description
7
RESP_DEMOD_EN1
R/W
0h
Enables respiration demodulation circuitry (ADS129xR only;
for ADS129x always write 0)
This bit enables and disables the demodulation circuitry on
channel 1.
0 = RESP demodulation circuitry turned off
1 = RESP demodulation circuitry turned on
6
RESP_MOD_EN1
R/W
0h
RESP_MOD_EN1: Enables respiration modulation circuitry
(ADS129xR only; for ADS129x always write 0)
This bit enables and disables the modulation circuitry on channel
1.
0 = RESP modulation circuitry turned off
1 = RESP modulation circuitry turned on
5
RESERVED
R/W
0h
Reserved
Always write 1h
4:2
RESP_PH[2:0]
R/W
0h
Respiration phase (1)
000 = 22.5°
001 = 45°
010 = 67.5°
011 = 90°
100 = 112.5°
101 = 135°
110 = 157.5°
111 = N/A
1:0
RESP_CTRL[1:0]
R/W
0h
Respiration control
These bits set the mode of the respiration circuitry.
00 = No respiration
01= External respiration
10 = Internal respiration with internal signals
11 = Internal respiration with user-generated signals
RESP_PH[2:0] phase control bits only for internal respiration (RESP_CTRL = 10) and external respiration (RESP_CTRL = 01) modes
when the CONFIG4.RESP_FREQ[2:0] register bits are 000b or 001b.
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9.6.1.17 CONFIG4: Configuration Register 4 (address = 17h) (reset = 00h)
Figure 90. CONFIG4: Configuration Register 4
7
6
RESP_FREQ[2:0]
5
4
0
R/W-0h
3
2
SINGLE_SHOT WCT_TO_RLD
R/W-0h
R/W-0h
R/W-0h
1
PD_LOFF_CO
MP
R/W-0h
0
0
R/W-0h
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset
Table 33. Configuration Register 4 Field Descriptions
(1)
Bit
Field
Type
Reset
Description
7:5
RESP_FREQ[2:0]
R/W
0h
Respiration modulation frequency
These bits control the respiration control frequency when
RESP_CTRL[1:0] = 10 or RESP_CTRL[1:0] = 10 (1).
000 = 64 kHz modulation clock
001 = 32 kHz modulation clock
010 = 16kHz square wave on GPIO3 and GPIO04. Output on
GPIO4 is 180 degree out of phase with GPIO3.
011 = 8kHz square wave on GPIO3 and GPIO04. Output on
GPIO4 is 180 degree out of phase with GPIO3.
100 = 4kHz square wave on GPIO3 and GPIO04. Output on
GPIO4 is 180 degree out of phase with GPIO3.
101 = 2kHz square wave on GPIO3 and GPIO04. Output on
GPIO4 is 180 degree out of phase with GPIO3.
110 = 1kHz square wave on GPIO3 and GPIO04. Output on
GPIO4 is 180 degree out of phase with GPIO3.
111 = 500Hz square wave on GPIO3 and GPIO04. Output on
GPIO4 is 180 degree out of phase with GPIO3.
Modes 000 and 001 are modulation frequencies in internal and
external respiration modes. In internal respiration mode, the
control signals appear at the RESP_MODP and RESP_MODN
terminals. All other bit settings generate square waves as
described above on GPIO4 and GPIO3.
4
RESERVED
R/W
0h
Reserved
Always write 0h
3
SINGLE_SHOT
R/W
0h
Single-shot conversion
This bit sets the conversion mode.
0 = Continuous conversion mode
1 = Single-shot mode
2
WCT_TO_RLD
R/W
0h
Connects the WCT to the RLD
This bit connects WCT to RLD.
0 = WCT to RLD connection off
1 = WCT to RLD connection on
1
PD_LOFF_COMP
R/W
0h
Lead-off comparator power-down
This bit powers down the lead-off comparators.
0 = Lead-off comparators disabled
1 = Lead-off comparators enabled
0
RESERVED
R/W
0h
Reserved
Always write 0h
These frequencies assume fCLK = 2.048 MHz.
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9.6.1.18 WCT1: Wilson Central Terminal and Augmented Lead Control Register (address = 18h) (reset =
00h)
The WCT1 control register configures the device WCT circuit channel selection and the augmented leads.
Figure 91. WCT1: Wilson Central Terminal and Augmented Lead Control Register
7
aVF_CH6
R/W-0h
6
aVL_CH5
R/W-0h
5
aVR_CH7
R/W-0h
4
aVR_CH4
R/W-0h
3
PD_WCTA
R/W-0h
2
1
WCTA[2:0]
R/W-0h
0
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset
Table 34. Wilson Central Terminal and Augmented Lead Control Field Descriptions
Bit
82
Field
Type
Reset
Description
7
aVF_CH6
R/W
0h
Enable (WCTA + WCTB)/2 to the negative input of channel 6
(ADS1296, ADS1296R, ADS1298, and ADS1298R)
0 = Disabled
1 = Enabled
6
aVL_CH5
R/W
0h
Enable (WCTA + WCTC)/2 to the negative input of channel 5
(ADS1296, ADS1296R, ADS1298, and ADS1298R)
0 = Disabled
1 = Enabled
5
aVR_CH7
R/W
0h
Enable (WCTB + WCTC)/2 to the negative input of channel 7
(ADS1298 and ADS1298R)
0 = Disabled
1 = Enabled
4
aVR_CH4
R/W
0h
Enable (WCTB + WCTC)/2 to the negative input of channel 4
0 = Disabled
1 = Enabled
3
PD_WCTA
R/W
0h
Power-down WCTA
0 = Powered down
1 = Powered on
2:0
WCTA[2:0]
R/W
0h
WCT Amplifier A channel selection, typically connected to
RA electrode
These bits select one of the eight electrode inputs of channels 1
to 4.
000 = Channel 1 positive input connected to WCTA amplifier
001 = Channel 1 negative input connected to WCTA amplifier
010 = Channel 2 positive input connected to WCTA amplifier
011 = Channel 2 negative input connected to WCTA amplifier
100 = Channel 3 positive input connected to WCTA amplifier
101 = Channel 3 negative input connected to WCTA amplifier
110 = Channel 4 positive input connected to WCTA amplifier
111 = Channel 4 negative input connected to WCTA amplifier
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9.6.1.19 WCT2: Wilson Central Terminal Control Register (address = 18h) (reset = 00h)
The WCT2 configuration register configures the device WCT circuit channel selection.
Figure 92. WCT2: Wilson Central Terminal Control Register
7
PD_WCTC
R/W-0h
6
PD_WCTB
R/W-0h
5
4
WCTB[2:0]
R/W-0h
3
2
1
WCTC[2:0]
R/W-0h
0
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset
Table 35. Wilson Central Terminal Control Field Descriptions
Bit
Field
Type
Reset
Description
7
PD_WCTC
R/W
0h
Power-down WCTC
0 = Powered down
1 = Powered on
6
PD_WCTB
R/W
0h
Power-down WCTB
0 = Powered down
1 = Powered on
5:3
WCTB[2:0]
R/W
0h
WCT amplifier B channel selection, typically connected to
LA electrode.
These bits select one of the eight electrode inputs of channels 1
to 4.
000 = Channel 1 positive input connected to WCTB amplifier
001 = Channel 1 negative input connected to WCTB amplifier
010 = Channel 2 positive input connected to WCTB amplifier
011 = Channel 2 negative input connected to WCTB amplifier
100 = Channel 3 positive input connected to WCTB amplifier
101 = Channel 3 negative input connected to WCTB amplifier
110 = Channel 4 positive input connected to WCTB amplifier
111 = Channel 4 negative input connected to WCTB amplifier
2:0
WCTC[2:0]
R/W
0h
WCT amplifier C channel selection, typically connected to
LL electrode.
These bits select one of the eight electrode inputs of channels 1
to 4.
000 = Channel 1 positive input connected to WCTC amplifier
001 = Channel 1 negative input connected to WCTC amplifier
010 = Channel 2 positive input connected to WCTC amplifier
011 = Channel 2 negative input connected to WCTC amplifier
100 = Channel 3 positive input connected to WCTC amplifier
101 = Channel 3 negative input connected to WCTC amplifier
110 = Channel 4 positive input connected to WCTC amplifier
111 = Channel 4 negative input connected to WCTC amplifier
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10 Application and Implementation
NOTE
Information in the following applications sections is not part of the TI component
specification, and TI does not warrant its accuracy or completeness. TI’s customers are
responsible for determining suitability of components for their purposes. Customers should
validate and test their design implementation to confirm system functionality.
10.1 Application Information
10.1.1 Setting the Device for Basic Data Capture
Figure 93 outlines the procedure to configure the device in a basic state and capture data. This procedure puts
the device into a configuration that matches the parameters listed in the Specifications section, in order to check
if the device is working properly in the user system. Follow this procedure initially until familiar with the device
settings. After this procedure has been verified, the device can be configured as needed. For details on the
timings for commands, refer to the appropriate sections in the data sheet. Sample programming codes are added
for the ECG-specific functions.
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Application Information (continued)
Analog/Digital Power-Up
Set CLKSEL Pin = 0
and Provide External Clock
fCLK = 2.048MHz
Yes
// Follow Power-Up Sequencing
External
Clock
No
Set CLKSEL Pin = 1
and Wait for Oscillator
to Wake Up
Set PDWN = 1
Set RESET = 1
Wait at least tPOR for
Power-On Reset
// If START is Tied High, After This Step
// DRDY Toggles at fCLK/8192
// (LP Mode with DR = fMOD/1024)
// Delay for Power-On Reset and Oscillator Start-Up
No
VCAP1 ³ 1.1V
// If VCAP1 < 1.1V at tPOR, continue waiting until VCAP1 ³ 1.1V
Yes
Issue Reset Pulse,
Wait for 18 tCLKs
Set PDB_REFBUF = 1
and Wait for Internal Reference
to Settle
// Activate DUT
// CS can be Either Tied Permanently Low
// Or Selectively Pulled Low Before Sending
// Commands or Reading/Sending Data from/to Device
Send SDATAC
Command
// Device Wakes Up in RDATAC Mode, so Send
// SDATAC Command so Registers can be Written
SDATAC
External
Reference
// If Using Internal Reference, Send This Command
WREG CONFIG3 0xC0
No
Yes
Write Certain Registers,
Including Input Short
// Set Device in HR Mode and DR = fMOD/1024
WREG CONFIG1 0x86
WREG CONFIG2 0x00
// Set All Channels to Input Short
WREG CHnSET 0x01
Set START = 1
// Activate Conversion
// After This Point DRDY Should Toggle at
// fCLK/4096
RDATAC
// Put the Device Back in RDATAC Mode
RDATAC
Capture Data
and Check Noise
// Look for DRDY and Issue 24 + n ´ 24 SCLKs
Set Test Signals
// Activate a (1mV ´ VREF/2.4) Square-Wave Test Signal
// On All Channels
SDATAC
WREG CONFIG2 0x10
WREG CHnSET 0x05
RDATAC
Capture Data
and Test Signal
// Look for DRDY and Issue 24 + n ´ 24 SCLKs
Figure 93. Initial Flow at Power Up
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Application Information (continued)
10.1.1.1 Lead-Off
Sample code to set dc lead-off with pullup or pulldown resistors on all channels:
WREG LOFF 0x13
//
//
WREG CONFIG4
0x02 //
WREG LOFF_SENSP 0xFF //
WREG LOFF_SENSN 0xFF //
Comparator threshold at 95% and 5%, pullup or pulldown resistor
dc lead-off
Turn on dc lead-off comparators
Turn on the P-side of all channels for lead-off sensing
Turn on the N-side of all channels for lead-off sensing
Observe the status bits of the output data stream to monitor lead-off status.
10.1.1.2 Right Leg Drive
Sample code to choose RLD as an average of the first three channels.
WREG RLD_SENSP 0x07
// Select channel 1-3 P-side for RLD sensing
WREG RLD_SENSN 0x07
// Select channel 1-3 N-side for RLD sensing
WREG CONFIG3
b’x1xx 1100 // Turn on RLD amplifier, set internal RLDREF voltage
Sample code to route the RLD_OUT signal through channel 4 N-side and measure RLD with channel 5. Make
sure the external side to the chip RLDOUT is connected to RLDIN.
WREG CONFIG3 b’xxx1 1100
WREG CH4SET b’1xxx 0111
WREG CH5SET b’1xxx 0010
// Turn on RLD amp, set internal RLDREF voltage, set RLD measurement bit
// Route RLDIN to channel 4 N-side
// Route RLDIN to be measured at channel 5 w.r.t RLDREF
10.1.1.3 Pace Detection
Sample code to select channel 5 and 6 outputs for pace:
WREG PACE b’0001 0101 // Power-up pace amplifier and select channel 5 and 6 for pace out
10.1.2 Establishing the Input Common-Mode
The ADS129x measures fully-differential signals where the common-mode voltage point is the midpoint of the
positive and negative analog input. The internal PGA restricts the common-mode input range because of the
headroom required for operation. The human body is prone to common-mode drifts because noise easily couples
onto the human body, similar to an antenna. These common-mode drifts may push the ADS129x input commonmode voltage out of the measurable range of the ADC.
If a patient-drive electrode is used by the system, the ADS129x includes an on-chip right leg drive (RLD)
amplifier that connects to the patient drive electrode. The RLD amplifier function is to bias the patient to maintain
the other electrode common-mode voltages within the valid range. When powered on, the amplifier uses either
the analog midsupply voltage, or the voltage present at the RLDREF pin, as a reference input to stabilize the
output near that voltage.
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Application Information (continued)
The ADS129x provide the option to use input electrode voltages as feedback to the amplifier to more effectively
stabilize the output to the amplifier reference voltage by setting corresponding bits in the RLD_SENSP and
RLD_SENSN registers. See to Figure 94 for an example of a three-electrode system that leverages this
technique.
RA
Anti-aliasing/
Protection
INxP
LA
Anti-aliasing/
Protection
INxN
ADS129x
RLDINV
1.5 nF
RL
1 M
RLDOUT
Protection
Figure 94. Setting Common-Mode Using RLD Electrode
A second strategy for maintaining a valid common-mode voltage is to ac-couple the analog inputs, which is
especially useful when a patient-drive electrode is not in use. A dc blocking capacitor combined with a voltage
divider between the analog power supplies, or a pullup resistor to set the DC bias to a known point, effectively
makes sure that the dc common-mode voltage never drifts. Applications that do not use a patient-drive electrode
may still use the RLD amplifier on the ADS129x as a buffered midsupply voltage to bias the inputs. Take care
when choosing the passive components because the capacitor and the resistors form an RC high-pass filter. If
passive components are chosen poorly, the filter undesirably attenuates frequencies at the lower end of the
signal band. Figure 95 shows an example of this configuration.
CBlock
RA
Anti-aliasing/
Protection
LA
Anti-aliasing/
Protection
INxP
CBlock
INxN
ADS129x
RPull-up
RPull-up
RLDINV
RLDOUT
Figure 95. Setting Common-Mode Without Using RLD Electrode
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Application Information (continued)
10.1.3 Antialiasing
As with all analog-to-digital systems, take care to prevent undesired aliasing effects. The ADS129x modulator
samples the input at either 256 kHz or 512 kHz, depending on whether the device is in low-power (LP) mode or
high-resolution (HR) mode, respectively. As is the case with all digital filters, the response of the on-chip digital
decimation filter on the ADS129x repeats at integer multiples of the modulator frequency. A benefit to using the
delta-sigma architecture is that the digital decimation filter significantly attenuates frequencies between the signal
band and the alias of the signal band near the modulator frequency. This attenuation, combined with the limited
bandwidth of the PGA (see Table 5), makes the requirement on the steepness of the response of the analog
antialiasing filter much less stringent. In many cases, acceptable attenuation at the modulator frequency is
provided by either a single or double-pole RC low pass filter.
Also take care when choosing components for antialiasing. Common-mode to differential-mode conversion as a
result of component mismatch, including antialiasing components, causes common-mode rejection degradation.
Figure 96 shows a typical front-end configuration.
R
INxP
C
ADS129x
R + /R
VP
INxN
C + /C
Figure 96. Typical Front-End Configuration
VP is the common-mode signal to the system. If the values of R and C modeled in the differential signal are
perfectly matched, then the system exhibits a very large CMR. If δR and δC in resistor R and capacitor C,
respectively, are mismatched, the CMR of the entire system is approximated to Equation 8.
f
/5 /&
) 20 log ( )
CMR 20 log (
fc
R
C
where
•
fC is the –3-dB frequency of the RC filter.
(8)
If 1%-precision external components are used and the bandwidth of the RC filter is approximately 6 kHz, the
system then has only 74 dB of CMR at 60 Hz. In the real world, the front-end of the ECG does not contain only
first-order RC filters; electrodes, cables, and second- or third-order RC filters are also included. Considering all of
these components, mismatch can easily accumulate, and thus contribute up to 20% or more of the signal. This
degree of mismatch degrades the CMR of the system to less than 60 dB at 60 Hz. Therefore, it is necessary to
consider different techniques to improve CMR.
There is a tradeoff when placing the bandwidth of the antialiasing filter in front of the modulator. Considering the
mismatch between the discrete components, it is better to select the large bandwidth; the upper limit of the
bandwidth is determined by the sampling frequency of the modulator. For more information on ways to prevent
common-mode rejection, see Improving Common-Mode Rejection Using the Right-Leg Drive Amplifier,
SBAA188.
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10.2 Typical Applications
10.2.1 ADS129xR Respiration Measurement Using Internal Modulation Circuitry
The respiration measurement circuitry on the ADS129xR employs out-of-band amplitude modulation and
demodulation to measure changes in thoracic impedance that correspond to breathing. When respiration mode is
enabled, channel 1 cannot be used to acquire ECG signals because the internal demodulation circuitry is unique
to that channel. ECG signals can still be acquired with the same electrodes used for respiration measurement if
they are also connected to another channel. Note the configuration shown in Figure 97.
R6
10MΩ
AVDD
R5
10MΩ
AVSS
IN1P
C1
470pF
C2
0.1µF
C3
2.2nF
ADS1294R/6R/8R
R2
40.2kΩ
RESP_MODP
Left Arm Lead
IN2P
IN2N
RESP_MODN
Right Arm Lead
C6
0.1µF
R4
10MΩ
C4
2.2nF
R1
40.2kΩ
C5
470pF
AVDD
R3
10MΩ
IN1N
AVSS
NOTE: Patient and input protection circuitry not shown.
Figure 97. Typical Respiration Circuitry
10.2.1.1 Design Requirements
Table 36 shows the design requirements for the components shown in Figure 97.
Table 36. Respiration Design Requirements
DESIGN PARAMETER
VALUE
Modulation frequency
32 kHz or 64 kHz
Input high-pass filter cutoff
≈ 68 Hz
ADC reference voltage
2.4 V
Maximum ac body current
100 μA
Minimum resistance R1 + R2
24 kΩ
10.2.1.2 Detailed Design Procedure
To configure the ADS129xR to use its internal modulation circuitry, set RESP register bits[6:7] to enable both the
internal modulation and demodulation circuitry. RESP register bits[4:2] determine the phase of the demodulation
blocking signal. To configure the device to use the internally generated signals for internal respiration
measurement, configure RESP register bits[1:0] to 10b.
The RESP_MODP and RESP_MODN pins produce a 32 kHz or 64 kHz square wave depending on the
CONFIG4 regsiter bits[7:5] when configured to use the internal circuitry. The REP_MODP and RESP_MODN pin
voltages toggle between VREFP and VREFN at opposite phases at the specified frequency.
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Choosing R1 and R2 involves first recognizing the ideal behavior of this circuit. Ideally, all of the series capacitors
appear as short-circuits to the high-frequency modulation signal, and there is no nonideal shunt capacitance
anywhere in the circuit. Figure 98 shows an equivalent circuit representing these assumptions.
R2
Rpp
RElectrode
IMOD
IN1P
RBaseline
VREF
IN1N
R1
ûR
Rpp
RElectrode
Figure 98. Ideal Behavior of the Respiration Modulation Circuit.
The voltage appearing at the channel 1 input is set by the voltage divider formed by the resistors in the circuit.
Resistor RPP represents any patient protection resistance in the cable; RElectrode represents the electrode-to-body
interface resistance; RBaseline represents the baseline body impedance; and ΔR is the change in thoracic
impedance due to respiration. Assume that R1 and R2 are significantly larger than all the other resistors in the
circuit, and then approximate the RESP_MOD pins as the terminals of an ac current source with magnitude IMOD
according to Equation 9:
VREF
IMOD |
R1 R2
where
•
VREF is the square wave with the amplitude VREFP – VREFN that is produced at the RESP_MOD pins.
(9)
According to IEC60601, patient current at a frequency of 32 kHz must be limited to less than 100 μA; this
limitation places a minimum value on the combination of R1 and R2.
For best performance, the inputs to the ADS129xR must be ac coupled and biased to midsupply. The
components that perform this function correspond to C1, C5, R3, R4, R5, and R6 in Figure 97. It is possible for
ECG interference to couple into channel 1. As a result of this possibility, it is advisable to make the high-pass
filter cutoff of those components large enough to attenuate the ECG bandwidth significantly. Conversely, if the
cutoff is set to high, the carrier signal may attenuate.
The signal that appears at the channel 1 input is amplified by the PGA, and then fed to the internal demodulation
block. The demodulation block removes the square wave from the input leaving only the very low-frequency
waveform corresponding to the ΔR due to respiration, and the offset due to RPP, RElectrode, and RBaseline.
Equation 10 describes the modulator output voltage corresponding to the change in body impedance.
VRESP IMOD u 'R u GPGA
(10)
Measure the rate of respiration by using the period at which VRESP oscillates as a result of ΔR. Make sure that
the magnitude of VRESP remains greater than the noise-free resolution of the ADS129x. This magnitude imposes
upper limits on the sizes of R1 and R2, as well as the cable impedance RPP, and demands that the quality of the
electrode-to-body connection is high.
Parasitic shunt capacitance tends to attenuate high frequencies and the outputs from the PGA are limited by the
bandwidth of the amplifiers. The result is that the square edges of the carrier are rounded. To account for this
error, the ADS129xR allows configuration of the RESP_PH[2:0] bits in the RESP regsiter. Those bits control the
demodulation phase that introduces a phase delay between the modulation and demodulation clocks to account
for the delay introduced by low-pass elements in the circuit.
Choosing the optimal phase depends on the system characteristics. The time constant introduced by the
resistance in the path of the input and the cable capacitance is an example of a system level characteristic that
influences the amount of phase required for optimal respiration rate measurement.
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Figure 99 shows a respiration test circuit. Figure 100 and Figure 101 plot noise on channel 1 for the ADS129xR
as baseline impedance, gain, and phase are swept. The x-axis is the baseline impedance, normalized to a 29-μA
modulation current (see Equation 11).
ADS129xR
IN1P
R2
40.2 kW
RESP_MODP
RBASELINE
2.21 kW
RESP_MODN
R2
40.2 kW
IN1N
Figure 99. Respiration-Noise Test Circuit
10
20
Phase = 112.5, PGA = 4
Phase = 112.5, PGA = 3
Phase = 135, PGA = 4
Phase = 135, PGA = 3
9
18
Channel 1 Noise (mVPP)
Channel 1 Noise (mVPP)
9.5
8.5
8
7.5
7
16
Phase = 135, PGA = 3
Phase = 135, PGA = 2
Phase = 157, PGA = 3
Phase = 157, PGA = 2
14
12
10
8
6.5
6
2214
3690
4845
8076
9155
15258
Normalized Baseline Respiration Impedance (W)
6
2214
3690
4845
8076
9155
15258
Normalized Baseline Respiration Impedance (W)
BW = 150 Hz, respiration modulation clock = 32 kHz
BW = 150 Hz, respiration modulation clock = 64 kHz
Figure 100. Channel-1 Noise vs Impedance for 32-kHz
Modulation Clock and Phase
Figure 101. Channel-1 Noise vs Impedance for 64-kHz
Modulation Clock and Phase
RNORMALIZED =
RACTUAL ´ IACTUAL
29mA
where
•
•
RACTUAL is the baseline body impedance.
IACTUAL is the modulation current, as calculated by (VREFP – VREFN) divided by the impedance of the
modulation circuit.
(11)
For example, assume that:
• Modulation frequency = 32 kHz
• RACTUAL = 3 kΩ
• IACTUAL = 50 μA
• RNORMALIZED = (3 kΩ × 50 μA) / 29 μA = 5.1 kΩ
Referring to Figure 100 and Figure 101, gain = 4 and phase = 112.5° yield the best performance at 6.4 μVPP.
Low-pass filtering this signal with a high-order, 2-Hz cutoff reduces the noise to less than 600 nVPP. The
impedance resolution is 600 nVPP / 29 μA = 20 mΩ. When the modulation frequency is 32 kHz, use gains of 3
and 4, and a phase of 112.5° and 135° for best performance. When the modulation frequency is 64 kHz, use
gains of 2 and 3 and phase of 135° and 157° for best performance.
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10.2.1.3 Application Curve
Figure 102 shows respiration data taken with the ADS1298RECGFE-PDK using the Fluke medSim 300b. The
data was then low-pass filtered to attenuate noise outside of the band of interest. A modulation frequency of
32 kHz was used along with a PGA gain of 3 and a RESP_PH setting of 112.5°.
15.9
15.89
15.88
15.87
Voltage (mV)
15.86
15.85
15.84
15.83
15.82
15.81
15.8
15.79
15.78
15.77
15.76
2
3
4
5
6
7
8
9
10 11 12 13 14 15 16 17 18 19 20
Time (s)
Figure 102. Respiration Impedance Taken With ADS1298R
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10.2.2 Software-Based Artificial Pacemaker Detection Using the PACEOUT Pins on the ADS129x
The electrical pulses produced by an artificial pacemaker are used to regulate the beating of the heart, and have
a very small duration (width) when measured on the scale of other biopotential signals. According to the standard
listed in AAMI EC11, medical instrumentation must be capable of capturing pacemaker pulses with durations as
narrow as 0.5 ms. The ADS129x is capable of capturing data at 32 kSPS; ideally, fast enough to capture even
the narrowest pulse. However, the data rate setting on the ADS129x is global for all channels. Using the
ADS129x to digitize an input channel fast enough for robust pacemaker detection dictates that all channels must
be converted as quickly; a condition that may be undesirable.
An alternative topology is to use the ADS129x internal pace buffers to route a single-ended version of any
particular channel input out to a fast-sampling SAR ADC to digitize the detection channel signal separately.
Detection of a pacemaker pulse is then performed in the digital domain. Refer to Figure 103 for the basic block
diagram for this architecture. The example features the combination of the OPA320 and the ADS7042. The
OPA320 is used to drive the input sampling structure of the ADS7042, but provides corollary flexibility to add
another gain stage and active antialias filtering before the pace output is digitized.
VCC
AVDD
IN1
IN2
IN3
IN4
IN5
IN6
IN7
IN8
RESPMOD
VCAP2
ADS129x
PACEOUT
SPI
SPI 1
CLK
GPIO
AVSS
Microcontroller
C1
VCC
VCC
R1
R2
R3
+
C2
C3
R6
R7
AVDD
OPA320
AINP
C4
í
C5
ADS7042 SPI
SPI 2
AINN
AVSS
R5
R4
Figure 103. Block Diagram of the Software Pacemaker Detection Topology
10.2.2.1 Design Requirements
Table 37 shows the design requirements for the components shown in Figure 103.
Table 37. Software Pace Design Requirements
DESIGN PARAMETER
VALUE
Analog supply voltage
3.3 V
Minimum pacemaker signal bandwidth
0.5 ms
Minimum pacemaker signal amplitude
2 mV
Feedback network R4 + R5 (nonunity gain)
≈ 100 kΩ
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10.2.2.2 Detailed Design Procedure
The pace amplifiers on the ADS129x provides differential to single-ended conversion and amplification of 0.4 V/V
to whatever voltage appears at the output of the PGA of the channel from which the pace amplifier is routed.
Selecting which channels are routed to the pace amplifiers is performed in the pace detect register of the
ADS129x. The voltage that appears at the output of the pace amplifier is to be taken with respect to analog
midsupply.
Before the signal is converted by the ADS7042, the signal must be buffered by a high-speed op amp because
the inputs of the ADS7042 represent a switch-capacitor type load. The OPA320 is ideal to perform this function
because of the low input bias current and 20-MHz unity gain bandwidth. The op amp also provides the flexibility
to provide an extra gain stage before the SAR ADC, isolate filter stages, or to provide simple buffering. The
purpose of C1 and R1 are to provide ac coupling to the pacemaker detection signal. This coupling may be
necessary because electrode offset and the pacemaker pulse can both be, in some cases, up to a few hundred
millivolts.
An actively-driven signal ground is required to set the dc bias of the op amp at midsupply. It is possible to use
the voltage provided at VCAP2 on the ADS129x as a buffered midsupply voltage. The voltage at the VCAP2 pin
may be noisy, but using it to drive the common-mode voltage for both inverting and noninverting inputs to the op
amp causes the op amp to cancel that noise significantly because it is common to both inputs.
Op amp feedback resistors R4 and R5 set the gain for the OPA320. The transfer function for this configuration is
that of the noninverting op amp configuration shown in Equation 12.
vo
v i (1 R3
)
R2
(12)
Resistors R4 and R5 are chosen to set the desired gain. The series combination is approximately 100 kΩ, so that
both the feedback current is limited to within the ADS129x VCAP2 internal regulator drive strength, and the
Johnson-Nyquist noise of the resistors remains negligible.
If the OPA320 is to be used only as a buffer, remove R4 removed to provide unity gain. If ac coupling is not
desired, for best performance, replace C1 with a 0-Ω resistor and depopulate R1.
The RC network of R2, C2, R3, C3, R6, C4, R7, and C5 form isolated two-pole RC antialiasing filters for the SAR
ADC. The component values of the filter are set to provide significant attenuation at the ADC sampling
frequency, but still provide enough bandwidth to detect a pacemaker pulse. A bandwidth of greater than 2 kHz is
enough to capture a narrow 0.5-ms pacemaker pulse.
In a real-time system, data must be collected and analyzed for a pacemaker with each incoming sample. Digitally
filter data that are collected from the ADS7042 to remove out-of-band noise. Unlike a delta-sigma converter, a
SAR converter does not apply a filter to the data before it is sent to the host. There are a number of factors that
drive a decision on digital-filter implementation. Some of those factors include steepness of the response, phase
linearity, and the number of taps. When using this topology with an ADS129xR device simultaneously with the
respiration measurement circuitry, take special care to remove noise generated by the respiration modulation
circuitry.
The key to detecting a pacemaker pulse is the detection of a steep transition in the input voltage. To measure
the magnitude of the transitions in input voltages, apply a digital differentiator algorithm. The algorithm measures
the change in voltage magnitude over the span of a few samples and compares the change to a threshold
required to trigger detection. The following pseudocode exemplifies some of the processing steps required to use
this topology:
newDataPoint = collectFromADS7042( );
// Collect data from the ADS7042
// Apply combined low-pass filter and differentiator
inputRateOfChange = LPFandDifferentiator( newDataPoint );
if( abs( inputRateOfChange ) > thresholdValue ) // Check if a quick edge occurred
{
pacemakerFlag = true;
// Edge detected
}
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10.2.2.3 Application Curve
Figure 104 shows data that was collected from the PACEOUT pin of the ADS1298R (using the OPA320 and the
ADS7042), and then filtered. The pacemaker pulse can be clearly identified.
0.12
0.1
0.08
Voltage (V)
0.06
0.04
0.02
0
-0.02
-0.04
-0.06
0.33 0.36 0.39 0.42 0.45 0.48 0.51 0.54 0.57 0.6 0.63 0.66
Time (s)
D001
NOTE: For illustration purposes, plot data were not processed in real time. As a result of the lack of shielding in this
particular configuration, data were also high-pass filtered to attenuate the utility noise.
Figure 104. Filtered ADS7042 Output Data With Pacemaker Pulse
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11 Power Supply Recommendations
The ADS129x have three power supplies: AVDD, AVDD1, and DVDD. For best performance, both AVDD and
AVDD1 must be as quiet as possible. AVDD1 provides the supply to the charge pump block and has transients
at fCLK. Therefore, star connect AVDD1 and AVSS1 to AVDD and AVSS. It is important to eliminate noise from
AVDD and AVDD1 that is nonsynchronous with ADS129x operation. Bypass each ADS129x supply with 1-μF
and 0.1-μF solid ceramic capacitors. For best performance, place the digital circuits (DSP, microcontrollers,
FPGAs, and so forth) in the system so that the return currents on those devices do not cross the analog return
path of the ADS129x. Power the ADS129x from unipolar or bipolar supplies.
Use surface-mount, low-cost, low-profile, multilayer ceramic-type capacitors for decoupling. In most cases, the
VCAP1 capacitor is also a multilayer ceramic; however, in systems where the board is subjected to high- or lowfrequency vibration, install a nonferroelectric capacitor, such as a tantalum or class 1 capacitor (C0G or NPO).
EIA class 2 and class 3 dielectrics such as (X7R, X5R, X8R, and so forth) are ferroelectric. The piezoelectric
property of these capacitors can appear as electrical noise coming from the capacitor. When using internal
reference, noise on the VCAP1 node results in performance degradation.
11.1 Power-Up Sequencing
Before device power up, all digital and analog inputs must be low. At the time of power up, keep all of these
signals low until the power supplies have stabilized, as shown in Figure 105.
Allow time for the supply voltages to reach their final value, and then begin supplying the master clock signal to
the CLK pin. Wait for time tPOR, then transmit a reset pulse using either the RESET pin or RESET command to
initialize the digital portion of the chip. Issue the reset after tPOR or after the VCAP1 voltage is greater than 1.1 V,
whichever time is longer. Note that:
• tPOR is described in Table 38.
• The VCAP1 pin charge time is set by the RC time constant; see Figure 31.
After releasing the RESET pin, program the configuration registers; see the CONFIG1: Configuration Register 1
(address = 01h) (reset = 06h) section for details. The power-up sequence timing is shown in Table 38.
tPOR(1)(2)
Supplies
tBG(1)
1.1V
VCAP1
VCAP = 1.1V
Start using
device
18 × tCLK
RESET
tRST
(1)
Timing to reset pulse is tPOR or after tBG, whichever is longer.
(2)
When using an external clock, tPOR timing does not start until CLK is valid.
Figure 105. Power-Up Timing Diagram
Table 38. Timing Requirements for Figure 105
MIN
tPOR
Wait after power up until reset
tRST
Reset low duration
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MAX
UNIT
218
tCLK
2
tCLK
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11.2 Connecting to Unipolar (3 V or 1.8 V) Supplies
Figure 106 illustrates the ADS129x connected to a unipolar supply. In this example, analog supply (AVDD) is
referenced to analog ground (AVSS) and digital supplies (DVDD) are referenced to digital ground (DGND).
+3V
+1.8V
0.1mF
1 mF
1mF
0.1mF
AVDD AVDD1
DVDD
VREFP
VREFN
10mF
0.1mF
VCAP1
VCAP2
ADS1298
RESV1
VCAP3
VCAP4
WCT
AVSS1 AVSS
1nF
DGND
1mF
1mF
0.1mF
1mF
22mF
NOTE: Place the capacitors for supply, reference, WCT, and VCAP1 to VCAP4 as close to the package as possible.
Figure 106. Single-Supply Operation
11.3 Connecting to Bipolar (±1.5 V or ±1.8 V) Supplies
Figure 107 illustrates the ADS129x connected to a bipolar supply. In this example, the analog supplies connect
to the device analog supply (AVDD). This supply is referenced to the device analog return (AVSS), and the
digital supply (DVDD) is referenced to the device digital ground return (DGND).
+1.5V
+1.8V
1mF
0.1mF
0.1mF
1 mF
AVDD AVDD1 DVDD
VREFP
VREFN
10mF
0.1mF
-1.5V
VCAP1
RESV1
ADS1298
VCAP2
VCAP3
VCAP4
WCT
AVSS1 AVSS
DGND
1nF
1mF
1mF
1 mF
0.1mF
1mF
22mF
0.1mF
-1.5V
NOTE: Place the capacitors for supply, reference, WCT, and VCAP1 to VCAP4 as close to the package as possible.
Figure 107. Bipolar Supply Operation
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12 Layout
12.1 Layout Guidelines
Use a a low-impedance connection for ground, so that return currents flow undisturbed back to their respective
sources. For best performance, dedicate an entire PCB layer to a ground plane and route no other signal traces
on this layer. Keep connections to the ground plane as short and direct as possible. When using vias to connect
to the ground layer, use multiple vias in parallel to reduce impedance to ground.
A mixed signal layout sometimes incorporates separate analog and digital ground planes that are tied together at
one location; however, separating the ground planes is not necessary when analog, digital and power supply
components are properly placed. Proper placement of components partitions the analog, digital and power
supply circuitry into different PCB regions to prevent digital return currents from coupling into sensitive analog
circuitry. If ground plane separation is necessary, then make the connection at the ADC. Connecting individual
ground planes at multiple locations creates ground loops, and is not recommended. A single ground plane for
analog and digital avoids ground loops.
Bypass supply pins with a low-ESR ceramic capacitor. The placement of the bypass capacitors must be as close
as possible to the supply pins using short, direct traces. For optimum performance, the ground-side connections
of the bypass capacitors must also be low-impedance connections. The supply current flows through the bypass
capacitor pin first and then to the supply pin to make the bypassing most effective (also known as a Kelvin
connection). If multiple ADCs are on the same PCB, use wide power-supply traces or dedicated power-supply
planes to minimize the potential of crosstalk between ADCs.
If external filtering is used for the analog inputs, use C0G-type ceramic capacitors when possible. C0G
capacitors have stable properties and low-noise characteristics. Ideally, route differential signals as pairs to
minimize the loop area between the traces. Route digital circuit traces (such as clock signals) away from all
analog pins. Note the internal reference output return shares the same pin as the AVSS power supply. To
minimize coupling between the power-supply trace and reference return trace, route the two traces separately;
ideally, as a star connection at the AVSS pin.
It is essential to make short, direct interconnections on analog input lines and avoid stray wiring capacitance,
particularly between the analog input pins and AVSS. These analog input pins are high-impedance and
extremely sensitive to extraneous noise. Treat the AVSS pin as a sensitive analog signal and connect directly to
the supply ground with proper shielding. Leakage currents between the PCB traces can exceed the input bias
current of the ADS129x if shielding is not implemented. Keep digital signals as far as possible from the analog
input signals on the PCB.
It is important the SCLK input of the serial interface is free from noise and glitches. Even with relatively slow
SCLK frequencies, short digital signal rise and fall times may cause excessive ringing and noise. For best
performance, keep the digital signal traces short, using termination resistors as needed, and make sure all digital
signals are routed directly above the ground plane with minimal use of vias.
Ground Fill or
Ground Plane
Supply
Generation
Microcontroller
Device
Optional: Split
Ground Cut
Signal
Conditioning
(RC Filters
and
Amplifiers)
Ground Fill or
Ground Plane
Optional: Split
Ground Cut
Ground Fill or
Ground Plane
Interface
Transceiver
Connector
or Antenna
Ground Fill or
Ground Plane
Figure 108. System Component Placement
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12.2 Layout Example
Figure 109 is an example layout of the ADS129x requiring a minimum of two PCB layers. The example circuit is
shown for either a single analog supply or a bipolar-supply connection. In this example, polygon pours are used
as supply connections around the device. If a three- or four-layer PCB is used, the additional inner layers can be
dedicated to route power traces. The PCB is partitioned with analog signals routed from the left, digital signals
routed to the right, and power routed above and below the device.
Via to AVSS pour
or plane
49: DGND
50: DVDD
51: DGND
52: CLKSEL
53: AVSS1
54: AVDD1
57: AVSS
58: AVSS
55: VCAP3
59: AVDD
56: AVDD
60: RLDREF
61: RLDINV
62: RLDIN
64: WCT
1: IN8N
48: DVDD
2: IN8P
47: DRDY
3: IN7N
46: GPIO4
4: IN7P
45: GPIO3
5: IN6N
44: GPIO2
6: IN6P
43: DOUT
7: IN5N
42: GPIO1
8: IN5P
41: DAISY_
IN
ADS129x
9: IN4N
40: SCLK
32: AVSS
31: RESV1
30: VCAP2
29: NC
28: VCAP1
27: NC
26: VCAP4
24: VREFP
33: DGND
25: VREFN
34: DIN
16: IN1P
22: AVDD
35:PWDN
15: IN1N
21: AVDD
36: RESET
14: IN2P
20: AVSS
37: CLK
13: IN2N
19: AVDD
38: START
12: IN3P
18: TESTN_
PACE_OUT2
39: CS
11: IN3N
17: TESTP_
PACE_OUT1
10: IN4P
23: AVSS
Input filtered with
differential and
common-mode
capacitors
63: RLDOUT
Via to digital ground
pour or plane
Long digital input lines
terminated with resistors
to prevent reflection
Reference, VCAP, and
power supply decoupling
capacitors close to pins
Figure 109. ADS129x Layout Example
Copyright © 2010–2015, Texas Instruments Incorporated
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Product Folder Links: ADS1294 ADS1294R ADS1296 ADS1296R ADS1298 ADS1298R
99
ADS1294, ADS1294R, ADS1296, ADS1296R, ADS1298, ADS1298R
SBAS459K – JANUARY 2010 – REVISED AUGUST 2015
www.ti.com
13 Device and Documentation Support
13.1 Related Links
Table 39 lists quick access links. Categories include technical documents, support and community resources,
tools and software, and quick access to sample or buy.
Table 39. Related Links
PARTS
PRODUCT FOLDER
SAMPLE & BUY
TECHNICAL
DOCUMENTS
TOOLS &
SOFTWARE
SUPPORT &
COMMUNITY
ADS1294
Click here
Click here
Click here
Click here
Click here
ADS1294R
Click here
Click here
Click here
Click here
Click here
ADS1296
Click here
Click here
Click here
Click here
Click here
ADS1296R
Click here
Click here
Click here
Click here
Click here
ADS1298
Click here
Click here
Click here
Click here
Click here
ADS1298R
Click here
Click here
Click here
Click here
Click here
13.2 Community Resources
The following links connect to TI community resources. Linked contents are provided "AS IS" by the respective
contributors. They do not constitute TI specifications and do not necessarily reflect TI's views; see TI's Terms of
Use.
TI E2E™ Online Community TI's Engineer-to-Engineer (E2E) Community. Created to foster collaboration
among engineers. At e2e.ti.com, you can ask questions, share knowledge, explore ideas and help
solve problems with fellow engineers.
Design Support TI's Design Support Quickly find helpful E2E forums along with design support tools and
contact information for technical support.
13.3 Trademarks
E2E is a trademark of Texas Instruments.
SPI is a trademark of Motorola Inc.
All other trademarks are the property of their respective owners.
13.4 Electrostatic Discharge Caution
These devices have limited built-in ESD protection. The leads should be shorted together or the device placed in conductive foam
during storage or handling to prevent electrostatic damage to the MOS gates.
13.5 Glossary
SLYZ022 — TI Glossary.
This glossary lists and explains terms, acronyms, and definitions.
14 Mechanical, Packaging, and Orderable Information
The following pages include mechanical, packaging, and orderable information. This information is the most
current data available for the designated devices. This data is subject to change without notice and revision of
this document. For browser-based versions of this data sheet, refer to the left-hand navigation.
100
Submit Documentation Feedback
Copyright © 2010–2015, Texas Instruments Incorporated
Product Folder Links: ADS1294 ADS1294R ADS1296 ADS1296R ADS1298 ADS1298R
PACKAGE OPTION ADDENDUM
www.ti.com
11-Nov-2014
PACKAGING INFORMATION
Orderable Device
Status
(1)
Package Type Package Pins Package
Drawing
Qty
Eco Plan
Lead/Ball Finish
MSL Peak Temp
(2)
(6)
(3)
Op Temp (°C)
Device Marking
(4/5)
ADS1294CZXGR
ACTIVE
NFBGA
ZXG
64
1000
Green (RoHS
& no Sb/Br)
SNAGCU
Level-3-260C-168 HR
0 to 70
ADS1294
ADS1294CZXGT
ACTIVE
NFBGA
ZXG
64
250
Green (RoHS
& no Sb/Br)
SNAGCU
Level-3-260C-168 HR
0 to 70
ADS1294
ADS1294IPAG
ACTIVE
TQFP
PAG
64
160
Green (RoHS
& no Sb/Br)
CU NIPDAU
Level-3-260C-168 HR
-40 to 85
ADS1294
ADS1294IPAGR
ACTIVE
TQFP
PAG
64
1500
Green (RoHS
& no Sb/Br)
CU NIPDAU
Level-3-260C-168 HR
-40 to 85
ADS1294
ADS1294RIZXGR
ACTIVE
NFBGA
ZXG
64
1000
Green (RoHS
& no Sb/Br)
SNAGCU
Level-3-260C-168 HR
-40 to 85
ADS1294R
ADS1294RIZXGT
ACTIVE
NFBGA
ZXG
64
250
Green (RoHS
& no Sb/Br)
SNAGCU
Level-3-260C-168 HR
-40 to 85
ADS1294R
ADS1296CZXGR
ACTIVE
NFBGA
ZXG
64
1000
Green (RoHS
& no Sb/Br)
SNAGCU
Level-3-260C-168 HR
0 to 70
ADS1296
ADS1296CZXGT
ACTIVE
NFBGA
ZXG
64
250
Green (RoHS
& no Sb/Br)
SNAGCU
Level-3-260C-168 HR
0 to 70
ADS1296
ADS1296IPAG
ACTIVE
TQFP
PAG
64
160
Green (RoHS
& no Sb/Br)
CU NIPDAU
Level-3-260C-168 HR
-40 to 85
ADS1296
ADS1296IPAGR
ACTIVE
TQFP
PAG
64
1500
Green (RoHS
& no Sb/Br)
CU NIPDAU
Level-3-260C-168 HR
-40 to 85
ADS1296
ADS1296RIZXGR
ACTIVE
NFBGA
ZXG
64
1000
Green (RoHS
& no Sb/Br)
SNAGCU
Level-3-260C-168 HR
-40 to 85
ADS1296R
ADS1296RIZXGT
ACTIVE
NFBGA
ZXG
64
250
Green (RoHS
& no Sb/Br)
SNAGCU
Level-3-260C-168 HR
-40 to 85
ADS1296R
ADS1298CZXGR
ACTIVE
NFBGA
ZXG
64
1000
Green (RoHS
& no Sb/Br)
SNAGCU
Level-3-260C-168 HR
0 to 70
ADS1298
ADS1298CZXGT
ACTIVE
NFBGA
ZXG
64
250
Green (RoHS
& no Sb/Br)
SNAGCU
Level-3-260C-168 HR
0 to 70
ADS1298
ADS1298IPAG
ACTIVE
TQFP
PAG
64
160
Green (RoHS
& no Sb/Br)
CU NIPDAU
Level-3-260C-168 HR
-40 to 85
ADS1298
ADS1298IPAGR
ACTIVE
TQFP
PAG
64
1500
Green (RoHS
& no Sb/Br)
CU NIPDAU
Level-3-260C-168 HR
-40 to 85
ADS1298
ADS1298RIZXGR
ACTIVE
NFBGA
ZXG
64
1000
Green (RoHS
& no Sb/Br)
SNAGCU
Level-3-260C-168 HR
-40 to 85
ADS1298R
Addendum-Page 1
Samples
PACKAGE OPTION ADDENDUM
www.ti.com
Orderable Device
11-Nov-2014
Status
(1)
ADS1298RIZXGT
ACTIVE
Package Type Package Pins Package
Drawing
Qty
NFBGA
ZXG
64
250
Eco Plan
Lead/Ball Finish
MSL Peak Temp
(2)
(6)
(3)
Green (RoHS
& no Sb/Br)
SNAGCU
Level-3-260C-168 HR
Op Temp (°C)
Device Marking
(4/5)
-40 to 85
ADS1298R
(1)
The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2)
Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check http://www.ti.com/productcontent for the latest availability
information and additional product content details.
TBD: The Pb-Free/Green conversion plan has not been defined.
Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements for all 6 substances, including the requirement that
lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes.
Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and package, or 2) lead-based die adhesive used between
the die and leadframe. The component is otherwise considered Pb-Free (RoHS compatible) as defined above.
Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame retardants (Br or Sb do not exceed 0.1% by weight
in homogeneous material)
(3)
MSL, Peak Temp. - The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature.
(4)
There may be additional marking, which relates to the logo, the lot trace code information, or the environmental category on the device.
(5)
Multiple Device Markings will be inside parentheses. Only one Device Marking contained in parentheses and separated by a "~" will appear on a device. If a line is indented then it is a continuation
of the previous line and the two combined represent the entire Device Marking for that device.
(6)
Lead/Ball Finish - Orderable Devices may have multiple material finish options. Finish options are separated by a vertical ruled line. Lead/Ball Finish values may wrap to two lines if the finish
value exceeds the maximum column width.
Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI bases its knowledge and belief on information
provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and
continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals.
TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release.
In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI to Customer on an annual basis.
Addendum-Page 2
Samples
PACKAGE MATERIALS INFORMATION
www.ti.com
2-Sep-2015
TAPE AND REEL INFORMATION
*All dimensions are nominal
Device
Package Package Pins
Type Drawing
ADS1294CZXGR
NFBGA
ZXG
64
ADS1294CZXGT
ADS1294IPAGR
NFBGA
ZXG
TQFP
PAG
ADS1294RIZXGR
NFBGA
ADS1294RIZXGT
SPQ
Reel
Reel
A0
Diameter Width (mm)
(mm) W1 (mm)
K0
(mm)
P1
(mm)
W
Pin1
(mm) Quadrant
8.3
2.25
12.0
16.0
Q1
1000
330.0
16.4
64
250
180.0
16.4
8.3
8.3
2.25
12.0
16.0
Q1
64
1500
330.0
24.4
13.0
13.0
1.5
16.0
24.0
Q2
ZXG
64
1000
330.0
16.4
8.3
8.3
2.25
12.0
16.0
Q1
NFBGA
ZXG
64
250
180.0
16.4
8.3
8.3
2.25
12.0
16.0
Q1
ADS1296CZXGR
NFBGA
ZXG
64
1000
330.0
16.4
8.3
8.3
2.25
12.0
16.0
Q1
ADS1296CZXGT
NFBGA
ZXG
64
250
180.0
16.4
8.3
8.3
2.25
12.0
16.0
Q1
ADS1296IPAGR
TQFP
PAG
64
1500
330.0
24.4
13.0
13.0
1.5
16.0
24.0
Q2
ADS1296RIZXGR
NFBGA
ZXG
64
1000
330.0
16.4
8.3
8.3
2.25
12.0
16.0
Q1
ADS1296RIZXGT
NFBGA
ZXG
64
250
180.0
16.4
8.3
8.3
2.25
12.0
16.0
Q1
ADS1298CZXGR
NFBGA
ZXG
64
1000
330.0
16.4
8.3
8.3
2.25
12.0
16.0
Q1
ADS1298CZXGT
NFBGA
ZXG
64
250
180.0
16.4
8.3
8.3
2.25
12.0
16.0
Q1
ADS1298IPAGR
TQFP
PAG
64
1500
330.0
24.4
13.0
13.0
1.5
16.0
24.0
Q2
ADS1298RIZXGR
NFBGA
ZXG
64
1000
330.0
16.4
8.3
8.3
2.25
12.0
16.0
Q1
ADS1298RIZXGT
NFBGA
ZXG
64
250
180.0
16.4
8.3
8.3
2.25
12.0
16.0
Q1
Pack Materials-Page 1
8.3
B0
(mm)
PACKAGE MATERIALS INFORMATION
www.ti.com
2-Sep-2015
*All dimensions are nominal
Device
Package Type
Package Drawing
Pins
SPQ
Length (mm)
Width (mm)
Height (mm)
ADS1294CZXGR
NFBGA
ZXG
64
1000
336.6
336.6
28.6
ADS1294CZXGT
NFBGA
ZXG
64
250
213.0
191.0
55.0
ADS1294IPAGR
TQFP
PAG
64
1500
367.0
367.0
45.0
ADS1294RIZXGR
NFBGA
ZXG
64
1000
336.6
336.6
28.6
ADS1294RIZXGT
NFBGA
ZXG
64
250
213.0
191.0
55.0
ADS1296CZXGR
NFBGA
ZXG
64
1000
336.6
336.6
28.6
ADS1296CZXGT
NFBGA
ZXG
64
250
213.0
191.0
55.0
ADS1296IPAGR
TQFP
PAG
64
1500
367.0
367.0
45.0
ADS1296RIZXGR
NFBGA
ZXG
64
1000
336.6
336.6
28.6
ADS1296RIZXGT
NFBGA
ZXG
64
250
213.0
191.0
55.0
ADS1298CZXGR
NFBGA
ZXG
64
1000
336.6
336.6
28.6
ADS1298CZXGT
NFBGA
ZXG
64
250
213.0
191.0
55.0
ADS1298IPAGR
TQFP
PAG
64
1500
367.0
367.0
45.0
ADS1298RIZXGR
NFBGA
ZXG
64
1000
336.6
336.6
28.6
ADS1298RIZXGT
NFBGA
ZXG
64
250
213.0
191.0
55.0
Pack Materials-Page 2
MECHANICAL DATA
MTQF006A – JANUARY 1995 – REVISED DECEMBER 1996
PAG (S-PQFP-G64)
PLASTIC QUAD FLATPACK
0,27
0,17
0,50
48
0,08 M
33
49
32
64
17
0,13 NOM
1
16
7,50 TYP
Gage Plane
10,20
SQ
9,80
12,20
SQ
11,80
0,25
0,05 MIN
1,05
0,95
0°– 7°
0,75
0,45
Seating Plane
0,08
1,20 MAX
4040282 / C 11/96
NOTES: A. All linear dimensions are in millimeters.
B. This drawing is subject to change without notice.
C. Falls within JEDEC MS-026
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