TI1 ADS126XEVM-PDK Evaluation module Datasheet

User's Guide
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ADS126xEVM-PDK
ADS126xEVM-PDK
This user's guide describes the operation and use of the ADS126x evaluation module (ADS126xEVM).
The ADS1262 and ADS1263 are low-noise, low-drift 32-bit delta-sigma analog-to-digital converters (ADC)
for precision industrial applications. The performance demonstration kit (PDK) is intended for prototyping
and evaluating the ADS1262 and ADS1263. The ADS126xEVM-PDK includes the ADS126xEVM daughter
card, MMB0 motherboard, A-to-B USB cable, 6-V wall-adapter power supply, and supporting software.
This document includes a detailed description of the hardware and software, bill of materials, and
schematic for the ADS126xEVM.
Throughout this document, the terms ADS126xEVM, demonstration kit, evaluation board, evaluation
module, and EVM are synonymous with the ADS126xEVM-PDK.
The following EVM-compatible devices and related documents are available through the Texas
Instruments website at www.ti.com.
Related Documents
Device
Literature Number
ADS1262
ADS1263
SBAS661
TPS79225
SLVS337B
TPS72325
SLVS346C
E2E is a trademark of Texas Instruments, Inc.
Windows XP, Windows 7 are trademarks of Microsoft Corporation.
X2Y is a registered trademark of X2Y Attenuators, LLC.
All other trademarks are the property of their respective owners.
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2
3
4
Contents
ADS126xEVM Overview .................................................................................................... 4
1.1
EVM Features ....................................................................................................... 4
1.2
Hardware Overview................................................................................................. 4
ADS126xEVM Hardware.................................................................................................... 5
2.1
Default Jumper and Switch Configuration ....................................................................... 5
2.2
Quick Reference .................................................................................................... 6
2.3
Power Supply........................................................................................................ 7
2.4
ADC Clock Source Options ...................................................................................... 11
2.5
Digital Interface, J1 ............................................................................................... 12
2.6
Analog Inputs ...................................................................................................... 13
ADS126xEVM Software ................................................................................................... 17
3.1
ADCPro and ADS126xEVM Plugin Installation................................................................ 17
3.2
Connecting the Hardware ........................................................................................ 17
3.3
Using ADCPro with the ADS126xEVM ......................................................................... 18
3.4
Using the ADS126xEVM Plugin ................................................................................ 20
ADS126xEVM Schematic and Bill of Materials ......................................................................... 31
4.1
Bill of Materials .................................................................................................... 31
List of Figures
1
ADS126xEVM Partitioning .................................................................................................. 4
2
ADS126xEVM connected to MMB0 motherboard ....................................................................... 4
3
Default Jumper and Switch Settings ...................................................................................... 5
4
Power Supply Circuitry Schematic
5
Power-Supply Circuitry (Default Jumper Settings) ...................................................................... 7
6
MMB0 Configuration for the 6-V Wall Adapter ........................................................................... 8
7
MMB0 Configuration for a Unipolar Bench Power Supply.............................................................. 9
8
MMB0 Configuration for a Bipolar Bench Power Supply .............................................................. 10
9
A) Schematic of ADS126xEVM Clocking Circuitry and B) Clocking Components on the ADS126xEVM ...... 11
10
Analog Input Support Circuitry on the ADS126xEVM ................................................................. 13
11
ADS126xEVM Ratiometric Connection Example ...................................................................... 15
12
J4 Thermocouple Input .................................................................................................... 16
13
Loading the ADS1262EVM Plugin in ADCPro
14
EVM Connection Status ................................................................................................... 18
15
ADS1262EVM Plugin Tabs ............................................................................................... 19
16
Loading a Test Plugin in ADCPro ........................................................................................ 19
17
Tab 1 Settings .............................................................................................................. 20
18
Tab 2 Settings .............................................................................................................. 21
19
Tab 3 Settings .............................................................................................................. 22
20
Tab 4 Settings .............................................................................................................. 23
21
Tab 5 Settings .............................................................................................................. 24
22
Tab 6 Settings .............................................................................................................. 25
23
Tab 7 Settings .............................................................................................................. 26
24
Tab 8: Register Map ....................................................................................................... 27
25
Tab 9: Register Map ....................................................................................................... 28
26
Tab 10: Extras / About ..................................................................................................... 29
27
Data Monitor Window ...................................................................................................... 30
28
Status Byte Error Pop-up .................................................................................................. 30
........................................................................................
.........................................................................
7
18
List of Tables
1
2
Factory Default Settings
....................................................................................................
ADS126xEVM-PDK
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Critical Connections ......................................................................................................... 6
3
J1, Serial Interface Header
4
ADS126x Analog Input Pin Functions ................................................................................... 14
5
ADS126xEVM Bill of Materials
...............................................................................................
..........................................................................................
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3
ADS126xEVM Overview
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ADS126xEVM Overview
The ADS126xEVM-PDK is an evaluation module using the MMB0 hardware and ADCPro software
platform for evaluation of the ADS1262 and ADS1263 (both referenced to as ADS126x in this document).
The standalone ADS126xEVM is useful for prototyping designs and firmware.
1.1
EVM Features
•
•
•
•
1.2
Includes all required support circuitry for the ADS1262 and ADS1263
ADCPro evaluation software for Windows XP™ and Windows 7™ operating systems, with built-in
analysis tools
Configurable inputs, references, supplies, and clock sources
Easily accessible signals through test points and headers
Hardware Overview
The EVM layout is partitioned as follows: the analog input/output (I/O) section, digital I/O header, power
components, and clock circuitry. All these sections connect to the ADS126x TSSOP package located in
the center of the EVM. Figure 1 visually identifies each of these areas on the EVM.
Analog I/O
Clock
ADS126x
Digital I/O
Power
Figure 1. ADS126xEVM Partitioning
Figure 2 shows the EVM connected to the MMB0 motherboard.
Figure 2. ADS126xEVM connected to MMB0 motherboard
The MMB0 provides two main functions:
1. Provides power to the ADS126xEVM
2. Interfaces between ADCPro and the ADS126x.
The default configuration of the MMB0 is sufficient to configure the ADS126x with a single supply. See
Section 2.3.2 to configure the EVM with bipolar supplies. A schematic of the MMB0 motherboard is
available at ftp://ftp.ti.com/pub/data_acquisition/ADCPro/Support/MMB0_Sch_RevD.PDF. The MMB0 is
intended to be used with the accompanying EVM software and does not have additional resources to
support the use as a firmware development platform.
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2
ADS126xEVM Hardware
This section provides details about the ADS126xEVM hardware.
2.1
Default Jumper and Switch Configuration
The ADS126xEVM is factory configured with the jumper and switch settings shown in Figure 3 and listed
in Table 1. The ADS126xEVM operates with these default settings using a single supply and external
crystal oscillator.
ADS126x
Figure 3. Default Jumper and Switch Settings
Table 1. Factory Default Settings
Name
Default Setting
JP1
Shorted
Shorts IN4 to IN6 (for two-wire ratiometric measurements)
JP2
Shorted
Used in conjunction with S1 for selecting or inputting the master clock
JP3
Shorted
Connects IN5 to AVSS to setup a current-controlled reference voltage across
R17
JP4
1-2, 3-4, and 5-6 shorted
JP5
Shorted
S1
1-2 (right)
S2
2-3 and 5-6 (left)
Function
Power supply connections to the ADS126x
Connects the thermocouple input J4.1 to AINCOM for biasing
Used in conjunction with JP2 to select master clock source
Selects unipolar or bipolar supplies for the ADS126x (the bipolar option
requires an additional bench supply)
NOTE:
•
•
Shorted jumpers on JP4 are required to connect the ADS126x to AVDD, AVSS,
and DVDD power supplies. These jumpers can be removed for measuring
current, or for connecting an external power supply.
The JP2, JP3, and JP5 jumpers are not required. Theses jumpers modify the
analog input connections for biasing and ratiometric measurements. See
Section 2.6 for more details.
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Quick Reference
Table 2 provides a quick summary of the key connections necessary for EVM operation. This information
is helpful when using an external processor or for monitoring EVM operation.
Table 2. Critical Connections
Function
SPI
Power
Analog inputs
6
Header (Pin)
Pin Name
Description
CS
J1.7
CS
Chip select
SCLK
J1.3
SCLK
Serial clock
DIN
J1.11
DIN
DOUT/DRDY
J1.13
DOUT
Data out
DRDY
J1.15
DRDY
Data ready
+3.3 V
J5.9
+3.3V
Digital supply
Analog supply
+5 V
Data in
J5.3
+5V
Channels 0-5
J3.1-6
AIN0-AIN5
Analog or reference inputs
Channels 6-7
J3.7-8
AIN6-AIN7
Analog inputs
Channels 8-9
J4.2,1
AIN8, AIN9
Thermocouple or analog inputs
Channel 10
J3.10
AINCOM
ADS126xEVM-PDK
Analog or common-reference
input
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2.3
Power Supply
The ADS126x operates either from a single 5-V supply or from bipolar ±2.5V supplies. By default, the
MMB0 and ADS126xEVM are configured for single 5-V supply operation using the included 6-V walladapter power supply. An additional –5-V supply voltage is required when using the ADS126xEVM with
bipolar supplies. Configuring the EVM and MMB0 for each of these cases is demonstrated in Section 2.3.1
and Section 2.3.2.
The ADS126xEVM is powered by the MMB0 motherboard, through the J5 header. The MMB0 is powered
through the 6-V wall adapter connected to J2. The MMB0 does not use USB power. Additional supplies
can be connected to the MMB0 through the J14 header. Figure 4 shows the relevant power supply
circuitry on the ADS126xEVM.
Supply Polarity
Switch
+5V
AVDD
6
Pos 2
Pos 1
GND
S2
5
3
4
U2
1
3
C27
1uF
IN
EN
1
3
5
Positive Supply
2
Negative Supply
DVDD
AVSS
2
4
6
DVDD
1
JP4
+3.3V
CAS-220TB
+5V
AVSS
AVDD
Power Measurement
or EXT Supply Jumpers
+2.5V
5
4
2
OUT
BYP
GND
C28
100nF
TPS79225DBVT
AVSS
DVDD
AVDD
2
AVDD
GND
GND
2
C32
1uF
3
IN
EN
C29
10uF
-2.5V
5
4
1
OUT
BYP
GND
D1
DDZ6V2B-7
C31
10uF
GND1
GND2
GND
GND
GND
AVSS
C33
100nF
TPS72325DBVT
GND
GND
C30
10uF
1
U3
-5V
GND
+5V
(-5V Supply must be supplied by user)
GND
+3.3V
-5V
1
2
3
4
5
6
7
8
9
10
-5V Input
Top and Bottom Side
(Bottom Connects to MMB0)
J5
DAUGHTER-POWER
MMB0 Signals
Signal Pin #
+VA
1
-VA
2
+5VA
3
-5VA
4
DGND
5
AGND
6
+1.8VD
7
VD1
8
+3.3VD
9
+5VD
10
Figure 4. Power Supply Circuitry Schematic
The JP4 jumpers are required to power the ADS126x. Removing these jumpers allows for an external
power supply connection or an ammeter connection to monitor the supply currents. Mini-clip test points
may also be used to connect to the ADS126xEVM supplies. Figure 5 shows the JP4 jumpers, switch S2,
and the power-supply test points.
Figure 5. Power-Supply Circuitry (Default Jumper Settings)
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Single 5-V Supply Configurations
To operate the EVM with a single 5-V supply, first check that switch S2 is in the default position (switched
to the left) and the JP4 jumpers are shorted as shown in Figure 5.
Next, configure the MMB0 motherboard in one of the following ways:
2.3.1.1
6-V, Wall-Adapter Power Supply (Default Configuration)
Make sure that the MMB0 jumpers J12 and J13B are shorted (default), as shown in Figure 6. In this
configuration, when the 6-V wall adapter is connected to J2, the MMB0 board generates the 5-V analog
supply and 3.3-V digital supply for the ADS126xEVM.
+6V wall-adapter jack
USB connector
Shorted jumpers (J12, J13B)
Figure 6. MMB0 Configuration for the 6-V Wall Adapter
NOTE: For clarity, the ADS126xEVM daughter card is not shown in Figure 6, Figure 7, or Figure 8.
The ADS126xEVM may need to be removed from the MMB0 motherboard to access the
MMB0 jumpers. Power down the MMB0 board when mounting or removing the
ADS126xEVM daughter card.
2.3.1.1.1
•
•
•
8
External Power-Supply Requirements
Nom Output Voltage: 6 VDC
Min Output Current: 500 mA
Efficiency Level V
NOTE: TI recommends using an external power supply that complies with applicable regional safety
standards such as (by example) UL, CSA, VDE, CCC, PSE, and so forth.
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2.3.1.2
Bench Power Supply
To use the MMB0 with an external bench power supply, remove the J12 jumper and leave it open, as
shown in Figure 7. Removing the jumper allows an external 5-V power supply to be connected to +5VA on
the J14 terminal block. Jumper J13B connects +5VA to +5VD and must remain shorted. In this
configuration, the MMB0 derives the 3.3-V digital supply for the ADS126xEVM from the 5-V bench supply,
and the bench supply directly supplies the analog supply voltage for the ADS126xEVM.
USB connector
+
±
Open jumper (J12)
5V
Power Input
Shorted jumper (J13B)
Figure 7. MMB0 Configuration for a Unipolar Bench Power Supply
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Bipolar ±2.5-V Supplies Configuration
To use the ADS126x with bipolar supplies, an external –5-V bench supply is required. If a negative supply
is not available, a positive 5-V supply capable of sinking current can be connected with reversed polarity.
First, configure the MMB0 in one of the configurations methods shown in Section 2.3.1.
Next, connect a –5-V supply to the -5VA net on terminal block J14, as shown in Figure 8.
After the MMB0 is configured, latch switch S2 (on the ADS126xEVM) into the 1-2 and 4-5 position
(switched to the right) to select the bipolar supply.
USB connector
5V
+
±
±
+
Open jumper (J12)
5V
Power Input
Shorted jumper (J13B)
Figure 8. MMB0 Configuration for a Bipolar Bench Power Supply
NOTE: The ADS126xEVM uses the power supply connections from +5VA, -5VA, +3.3VD, and GND
on the MMB0 board.
MMB0 jumper J13A has no effect on the circuit behavior of the ADS126xEVM as long as no
other supply is connected to +VA. Do not short jumper J13A when another supply is
connected to +VA.
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2.4
ADC Clock Source Options
The ADS126x requires a master clock to operate the delta-sigma modulator. The clock frequency, fCLK, is
directly proportional to the modulator's sampling rate, fMOD (= fCLK/8). Consequently, the ADC output data
rate follows the modulator sampling rate divided by the overall decimation ratio set by the digital filter. This
clock can be supplied by the ADS126x internal oscillator, by the X1 crystal oscillator on the ADS126xEVM,
or by an external clock source. The clock source is determined by switch S1 and jumper JP2. Figure 9
shows the relevant clocking circuitry on the ADS126xEVM.
A)
B)
Figure 9. A) Schematic of ADS126xEVM Clocking Circuitry and B) Clocking Components on the
ADS126xEVM
Use one of the following clocking options:
1. Onboard 7.3728 MHz Crystal Oscillator (Default Configuration)
The ADS126xEVM has an onboard crystal oscillator (component X1). The crystal oscillator clock is
detected by the ADS126x when switch S1 is in the 1-2 position (switched to the right, as shown in
Figure 9B).
2. ADS126x Internal 7.3728 MHz Oscillator
The ADS126x selects the internal oscillator when no external clock is detected. To use this mode,
ground the XTAL1/CLKIN input by switching S1 to the 2-3 position (switched to the left) and float the
XTAL2 input by shorting jumper JP2.
3. External Clock Source
If an alternate clock source or frequency is preferred, apply the external clock to the XTAL1/CLKIN
input, and float XTAL2. The ADS126xEVM provides for this external clock connection. Remove jumper
JP2 and apply the clock to the JP2 jumper posts. Configure switch S1 to the 2-3 position (switched to
the left). The external clock source must have a frequency between 1 MHz and 8 MHz, and have a
peak-to-peak amplitude equal to the DVDD supply voltage.
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Digital Interface, J1
The J1 header (top) and socket (bottom) provide access to the digital controls and serial data pins of the
ADS126x. These signals can be connected to a development platform for software development. All logic
levels are referenced to the digital supply voltage (the MMB0 provides a 3.3-V digital supply to the
ADS126xEVM through pin J5.9). Table 3 describes the J1 serial interface pins.
Table 3. J1, Serial Interface Header
Function
Signal Name
Unused
SPI clock
SCLK
Unused
Serial port active low chip
select (100-kΩ pull-up)
Pin Number
(J1)
1
2
3
4
5
6
CS
7
8
9
10
Serial port data input
DIN
11
12
Serial port data output and
data ready indicator (active
low)
DOUT/DRDY
13
14
Data ready indicator (active
low)
DRDY
Unused
Signal Name
Function
START
Start conversion control
(100-kΩ pull-up)
GND
Ground
RESET/PWDN
Reset (active low) or hold
low to power-down the
ADC (100-kΩ pull-up)
Unused
GND
Ground
Unused
Unused
15
16
Unused
17
18
GND
Ground
Unused
19
20
SDA
I2C data (for EEPROM)
NOTE:
SCL
I2C clock (for EEPROM)
Keep all connections to the ADS126xEVM as short as possible. If jumper wiring is used to
connect a software development board to the ADS126xEVM, keep a ground connection
(wire) between boards close to all of the digital signals (wires). A large loop area between
ground and digital signals creates inductive connections and poor signal integrity.
When probing SPI communications, check the signal integrity near the receiving end (that is,
probe DIN at the ADS126x input, not at the SPI controller output).
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2.6
Analog Inputs
The ADS126x has a total of 11 analog input pin: AIN0 through AIN9 plus a common reference input,
AINCOM. This design allows the ADS126x to be configured for up to five differential input pairs, ten
single-ended inputs referenced to a common voltage, or a combination of single-ended and differential
inputs. The flexible input multiplexer of the ADS126x allows any two inputs to be selected for either the
positive or negative ADC input.
When measuring single-ended input signals, any input pin may be used as a common voltage reference.
However, AINCOM is specially designated to serve this purpose because it provides a bias voltage (levelshift function) for floating sensors to meet the common-mode voltage requirements of the ADS126x inputs.
All of the analog inputs to the ADC are pinned out on the ADS126xEVM. The supporting circuitry provides
filtering and ratiometric connections for a variety of sensors. Additionally, a separate terminal block (J4) is
provided for thermocouple inputs. Figure 10 shows the schematic of the ADS126xEVM analog input
circuitry.
IN1
IN0
R1 47
C1
47pF
R2
NI
GND
R6 47
IN1
J2
1
IN0
2
IN1
3
IN2
4
IN3
5
IN4
AIN0
(EXT REF1 P)
X2Y Capacitor
C2 NI
C3
100nF
GND
GND
C4
47pF
AIN1
(EXT REF1 N)
IN2
IN2
6
IN5
7
IN6
8
IN7
9
AINCOM
R8 47
C7
47pF
R10
NI
IN3
GND
R12 47
AIN2
(EXT REF2 P)
X2Y Capacitor
C8 NI
C9
100nF
GND
GND
C11
47pF
AIN3
(EXT REF2 N)
10
ED555/10DS
TERMINAL BLOCK
Top Side
GND
Ratiometric
Connection
Jumper
1 IN6
2 IN4
JP1
IN4
R16 47
1
IN0
2
IN1
3
IN2
4
IN3
5
IN4
6
IN5
7
IN6
8
IN7
R17
3.9k
R17 sets up a 1.95V reference
voltage with 500uA IDAC
IN5
R19
620
AINCOM1
AINCOM
C22
47pF
AIN5
(EXT REF3 N)
AVSS Connection
Jumper
JP3
R19 increases REF3N voltage to >0.3V when used with
500uA IDAC in single supply and ratiometric configurations
AVSS
IN6
R20 47
13
AIN6
(Test SIG P)
X2Y Capacitor
C24 NI
C23
47pF
GND
14
GND
R18 47
2
1
10
12
C18
GND
100nF
GND
C21
47pF
9
11
AIN4
(EXT REF3 P)
X2Y Capacitor
C17 NI
C16
47pF
J3
15
C25
GND
100nF
GND
16
GND
C26
47pF
17
IN7
R21 47
AIN7
(Test SIG N)
18
20
DAUGHTER-ANALOG
Bottom Side
(Connects to MMB0)
INPUT FILTERING
REFOUT1
19
CM f-3dB = 72 MHz
DM f-3dB = 16.9 kHz
REFOUT
GND
MMB0 passes signals through to J10
2.2k @ 25°C
t° RT1
R22
Thermistor (for CJC)
R23 NI
12k
R24
Configured for 250uA IDAC
in single supply configuration
(Install 0-Ohms in R22 & R24)
IN6
IN7
NI
R25
1.2k
X2Y Capacitor
R26 499
AIN8
C34
1nF
J4
Thermocouple
Input
GND
GND
2
1
R28 499
R31
NI
ED555/2DS
TERMINAL BLOCK
Top Side
C37
1nF
C35 NI
C36
100nF
GND
GND
AIN9
FILTERING
CM f-3dB = 319 kHz
DM f-3dB = 1.59 kHz
Cold Junction = GND
GND
1
2
Sensor Bias
Jumper
AINCOM
JP5
Figure 10. Analog Input Support Circuitry on the ADS126xEVM
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ADS126x Integrated Input Functions
The ADS1262 and ADS1263 provide several integrated functions on the analog inputs to support many
applications. Table 4 summarizes the functions available on each input pin.
Table 4. ADS126x Analog Input Pin Functions
2.6.1.1
Input Pin
ADC Input
IDAC Output
VBIAS Output
External REF Input
Test DAC Output
GPIO
AIN0
yes
yes
-
REF1 P
-
-
AIN1
yes
yes
-
REF1 N
-
-
AIN2
yes
yes
-
REF2 P
-
-
AIN3
yes
yes
-
REF2 N
-
yes
AIN4
yes
yes
-
REF3 P
-
yes
AIN5
yes
yes
-
REF3 N
-
yes
AIN6
yes
yes
-
-
yes
yes
AIN7
yes
yes
-
-
yes
yes
AIN8
yes
yes
-
-
-
yes
AIN9
yes
yes
-
-
-
yes
AINCOM
yes
yes
yes
-
-
yes
ADC Inputs
The ADS126x has a flexible input multiplexer with 11 analog inputs. Any of the inputs can connect to the
positive input and any input can connect to the negative input. (Additionally, the ADS1263 has a second
ADC with an independent flexible input multiplexer to all input pins). Configure the inputs to provide either
single-ended or differential input measurements. The input multiplexer can also connect to several internal
signals. The internal signals are the temperature sensor, test DAC, analog power supply ([AVDD – AVSS]
/ 4), and digital power supply ([DVDD – DGND] / 4). Use the internal signals for ADC and system
functional verification or as part of an ADC diagnostic routine.
2.6.1.2
IDAC Output
The ADS126x provides dual matched current sources (IDAC1 and IDAC2) for biasing of resistive
temperature devices (RTDs), thermistors and other resistive based sensors. The IDACs can be
independently programmed and can be connected to any analog input. Each IDAC is programmable over
the range of 50 µA to 3000 µA. The internal reference must be enabled for IDAC operation.
2.6.1.3
VBIAS Output
The analog power supply is either a single or bipolar supply. For single-supply operation, the level shift
function (VBIAS) can offset the common input voltage on AINCOM to a midsupply voltage ([AVDD +
AVSS] / 2).
2.6.1.4
External REF Input
The ADC126x accepts external references (in addition to the internal and supply reference options). The
external reference inputs are shared with pins AIN0 through AIN5. ADC2 (on the ADS1263) selects a
different reference source other than the primary ADC.
2.6.1.5
Test DAC Output
Inputs AIN6 and AIN7 are programmable to output the internal test DAC voltage. The test signal output is
unbuffered; do not externally load.
2.6.1.6
GPIO
Eight inputs (AIN3 through AINCOM) are configurable as general-purpose input/outputs (GPIO). The
GPIO voltages are referenced to the analog power supply (AVDD and AVSS); therefore, the GPIOs must
use 5-V logic. The GPIOs are useful for control of external devices, as well as reading external logic
signals.
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2.6.2
Using the ADS126xEVM for Ratiometric Measurements
Ratiometric measurements are often used with resistive-type sensors requiring a current excitation source
(such as an RTD). The current is forced through the resistive sensor to generate a voltage signal for the
ADC input. If the current source deviates from the programmed value (because of drift or noise), an
apparent change in resistance is observed by the ADC. To correct for this error, the current source is also
forced through a precision resistor to generate the ADC reference voltage. In this ratiometric configuration,
a change in current directly affects the ADC input signal and reference voltage proportionally. Therefore,
the ratio of the input signal to reference voltage remains constant for a given sensor impedance.
A simple block diagram of a ratiometric connection, using a 3-wire RTD with the ADS126xEVM, is shown
in Figure 11. The 3-wire RTD is connected to the J2 header on inputs IN7, IN6, and IN4. Two IDACs
output 250 µA (each) on pins AINCOM and AIN3 of the ADS126x. Jumper wires then connect IN7 to
COM, and IN6 to IN3. These jumper wires route the IDAC currents around the input filtering to prevent
voltage drops in the input signal path. IDAC current flow thought the R17 resistor, between IN4 and IN5, to
provide the ratiometric voltage reference. IDAC currents are routed to AVSS through JP3, or directly to
ground by connecting another jumper wire between IN5 and GND.
3-Wire
RTD
COM
AINCOM
ADS126x
IN7
AIN7
PGA
IN6
AIN3
AIN4
IN4
500 uA
Alternate Bias
Connection
REF
JP1
IN3
IN5
ADC1
AIN6
AIN5
+
R17
3.9k 1.95 V
-
JP3
GND
+
R19
620 0.31 V
AVSS
ADS126xEVM
Figure 11. ADS126xEVM Ratiometric Connection Example
NOTE: The purpose of R19 is to boost up the negative reference voltage when using a singlesupply configuration. However, the ADS126x allows for the negative reference voltage to be
connected directly to AVSS (when used with a bipolar supply) or GND potential (when used
with a single supply). Short R19 or replace with a 0-Ω resistor to allow additional headroom
for the IDAC compliance voltage.
Although this example shows a 3-wire RTD, the ADS126x can also support 2- or 4-wire RTDs. For a 2wire RTD, use JP1 to replace the IN4 connection. For a 4-wire RTD, remove the IN6 to IN3 jumper wire,
remove the IN7 to COM jumper wire, and connect the additional RTD wire to COM.
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Thermocouple Input
Terminal block J4, shown in Figure 12, connects to inputs AIN8 and AIN9 on the ADS126x. The terminal
block is surrounded by a cutout ground plane polygon to provide partial thermal isolation for thermocouple
inputs. Thermocouples can be biased either by enabling the VBIAS level shifter and shorting jumper JP5,
or by enabling the 1-MΩ pull-up and pull-down resistors inside the ADS126x.
Figure 12. J4 Thermocouple Input
Cold junction compensation of the thermocouple is implemented by the thermistor on RT1 to measure the
cold junction temperature. Install 0-Ω resistors on R22 and R24 (0603 surface-mount pads) to connect
RT1 to inputs AIN6 and AIN7 on the ADS126x. R23 is in parallel with RT1 for linearization of the
thermistor resistance versus temperature transfer function.
NOTE:
2.6.4
Do not use the IN6 and IN7 inputs on terminal block J2 if components are soldered to R22
or R24. Interaction between components causes measurement error.
X2Y® Capacitor Footprints
Capacitors C2, C8, C17, C24, and C35 are unpopulated footprints reserved for 0603 X2Y capacitors. X2Y
capacitors can replace the multiple capacitors (C1, C3, and C4 for example) required for common-mode
and differential filtering. In addition to the board space saved by using X2Y, these capacitors have lower
ESL and excellent common-mode capacitor matching.
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3
ADS126xEVM Software
This section explains setup and use of the ADS126xEVM software. Software setup requires installing
ADCPro (a tool used to acquire and analyze ADC data), and installing an EVM specific plugin to use
within ADCPro. Download the ADCPro user's guide from http://www.ti.com/lit/ug/sbau128c/sbau128c.pdf.
3.1
ADCPro and ADS126xEVM Plugin Installation
1. Install ADCPro
Download the ADCPro installer from http://www.ti.com/adcpro. The ADCPro Hardware and Software
Installation Manual provides a step-by-step installation procedure. Install ADCPro first before installing
the ADS126xEVM plugin.
2. Install the ADS126xEVM Plugin
Download the ADS126xEVM plugin installer from http://www.ti.com/tool/ads1262evm-pdk or
http://www.ti.com/tool/ads1263evm-pdk. Run the ADS126x plugin installer after installing ADCPro.
NOTE: The ADS126xEVM plugin installer runs an additional installation for the USBStyx driver
required to communicate with the MMB0. If the software is unable to connect to the EVM,
this driver may not have properly installed. This driver may be reinstalled with one of the
installers located at ftp://ftp.ti.com/pub/data_acquisition/ADCPro2/misc/drivers/. Use the
installer version (32- or 64-bit) that corresponds to the version of your operating system.
3.2
Connecting the Hardware
After ADCPro and the ADS126xEVM plugin have been installed, connect the hardware, and then run
ADCPro.
To connect the hardware, follow these steps:
1. If disconnected, connect the ADS126xEVM daughter card to the MMB0 motherboard while powered off
(as shown in Figure 2).
2. Check and configure jumper and switch settings on the MMB0 and ADS126xEVM, as described in
Section 2.3.
3. Connect any sensors or external test circuitry to the ADS126xEVM.
4. Connect the USB cable from the MMB0 to the computer.
5. Power up the MMB0 (and ADS126xEVM) with the included wall adapter or an external bench supply.
6. After powering up the MMB0 and ADS126xEVM, power up any other external circuitry.
7. Run ADCPro and follow the steps in Section 3.3 to communicate with the ADS126xEVM.
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Using ADCPro with the ADS126xEVM
For more information about ADCPro than is provided in this document, refer to the ADCPro User's Guide,
SBAU128. This section covers only the functionality of the ADS126xEVM plugin. After the hardware is
connected, powered up, and ADCPro is running, follow these steps to establish communication with the
ADS126xEVM:
1. Load the ADS126xEVM plugin by clicking ADS126XEVM from the EVM file menu shown in Figure 13.
This step can be repeated to reload the plugin. The plugin may need to be reloaded in the case of a
communication failure or if power is cycled on the EVM hardware.
Figure 13. Loading the ADS1262EVM Plugin in ADCPro
2. Wait for the Connected to EVM status seen in Figure 14. If the connection fails, reset the hardware
either by pushing the reset button in the upper right corner of the MMB0 or by cycling MMB0 power. If
a connection cannot be established after resetting the MMB0, refer back to Section 3.1 and Section 3.2
for the required drivers and hardware connections.
Figure 14. EVM Connection Status
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3. Configure the ADS126x. The ADS126xEVM plugin is divided into ten tabs, as shown inFigure 15.
Clicking on a tab changes the displayed controls. The controls on each tab are described in
Section 3.4.
1 Input MUX
7 Data \ MODE
2 Reference
8 Calibration
3 Digital Filter
9 Register Map
4 IDAC / Sensor Bias
5 GPIO
10 Extras / About
6 Test DAC
Figure 15. ADS1262EVM Plugin Tabs
4. Select a test plugin from the Test file menu, as shown in Figure 16. This step may precede steps 1 to
3, but is required before acquiring data in the next step.
Figure 16. Loading a Test Plugin in ADCPro
5. Acquire data by clicking the Acquire or Continuous button (previously shown in Figure 14). These
buttons are only operational when both the EVM and test plugins are loaded. Clicking Acquire captures
a single block of data. Clicking Continuous captures blocks of data repeatedly. The block size is
configured in the test plugin.
6. Use the test plugin functions as described in the ADCPro User's Guide, SBAU128, to analyze the ADC
conversion data.
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Using the ADS126xEVM Plugin
This section describes the controls in the ADS126xEVM plugin. Additional details about specific ADS126x
functions can be found in the ADS1262 and ADS1263 data sheet, SBAS661.
3.4.1
Tab 1: Input MUX
The controls on tab 1 select the ADC inputs from the internal multiplexer (mux) and control the PGA
settings. Click the radio buttons to independently select the positive (AINPx) and negative (AINNx) ADC
inputs. Clicking the TEMP, AVDD, DVDD, or TDAC special function inputs selects that function for both
inputs, and configures the PGA as recommended. Note that the ADC2 radio buttons are only visible when
an ADS1263EVM is connected.
Clicking the AINCOM button enables the VBIAS level shifter. Both the VBIAS level shifter and Chop
functions can be configured on tab 1 and tab 4 (IDAC \ Sensor Bias).
To test the ADC noise performance, select the same input signal for AINP and AINN to internally short the
ADC inputs. Remember to set a proper common-mode input voltage by applying an external midsupply
voltage or by using the VBIAS function on AINCOM, as shown in Figure 17.
1 Input MUX
Figure 17. Tab 1 Settings
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3.4.2
Tab 2: Reference
Figure 18 shows the tab used to configure the ADCx reference source. The voltage reference source is
selected from the ADCx REF Source drop-down menu. When using an external source for ADC1, the
positive and negative reference inputs must be specified by the REFP and REFN drop-down menus.
Selecting the Invert ADC1 REF Inputs checkbox swaps the positive and negative reference inputs, and
allows for fully flexible reference source inputs.
2 Reference
Figure 18. Tab 2 Settings
When using an external reference source for ADC1, also make sure that the ADC1 REF Voltage field is
matched to the applied reference voltage to allow ADCPro to correctly convert the output data from codes
to volts. The internal reference can be disabled when an external referenced is used; however, the internal
reference must be enabled to use the IDACs.
The ADC2 Reference Settings are only visible when an ADS1263EVM is connected.
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Tab 3: Digital Filter
Tab 3 contains the filter and data rate selection controls, as shown in Figure 19.
3 Digital Filter
Figure 19. Tab 3 Settings
The ADC1 Filter Settings section controls both the digital filter type and the data rate for ADC1. When the
FIR filter is selected, data rates are limited to frequencies that support 50-Hz or 60-Hz line cycle rejection.
Note that because of speed limitations within the firmware, the 19.2 kSPS and 38.4 kSPS data rates are
only available when Data Collection Mode is set to ADC1 on Tab 7 (Data \ MODE).
The ADC2 Filter Settings controls are shown only when an ADS1263EVM is connected. The SINC3 filter
is the only filter available for ADC2.
NOTE: Data from ADC2 are only collected when Data Collection Mode is set to ADC1 + ADC2 on
Tab 7 (Data \ MODE).
ADC2 Data Rate must be at least ½ the ADC1 Data Rate setting because the firmware only
polls for new ADC2 data when an ADC1 conversion completes. Setting the ADC2 Data Rate
much slower than ½ the ADC1 Data Rate may require a much longer collection time.
ADC1 and ADC2 do not sample simultaneously.
Changing ADC filter and data rate settings, the chopping settings on tab 4 (IDAC \ Sensor Bias), or the
fCLK control, updates the Filter Response plot. This plot can be scaled by the controls below the plot or by
clicking and typing a new value into an existing axis value.
NOTE: Make sure that the fCLK frequency input is correct (there is no need to modify fCLK when
using the ADS126x internal oscillator or the ADS126xEVM's default X1 crystal).
The fCLK frequency affects the calculated ADC1 Data Rate and ADC2 Data Rate indicators
that are also used by the software when acquiring data, plotting the filter response, or
calculating the FFT in the MultiFFT test plugin.
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3.4.4
Tab 4: IDAC / Sensor Bias
Figure 20 shows the IDAC \ Sensor Bias tab controls. The IDAC Configuration controls configure the IDAC
direction, magnitude, and rotation. The IDACs require the internal reference to be enabled on tab 2
(Reference).
4 IDAC / Sensor Bias
Figure 20. Tab 4 Settings
The Sensor Bias Settings controls are used to enable burnout current sources or bias resistor connections
prior to ADC1 (or ADC2) for detecting sensor open circuits or biasing floating sensors. Only use burnout
current sources to verify the sensor connection. For best results, disable the burnout current source after
the sensor connection is verified and before measuring the sensor output. Make sure to account for the
analog filter settling time when enabling or disabling the burnout current source.
The Additional Settings controls configure other sensor bias-related functions:
Input Chop— enables or disables the global input chop feature of the ADS126x.
When enabled, input chopping reduces offset and offset drift errors.
Settling Delay— configures the initial conversion delay before ADC1 begins converting.
The default settling delay provides time for PGA1 to settle when a step input occurs.
AINCOM Bias— enables or disables the mid-supply level-shift function on the AINCOM pin
Input Chop and AINCOM are duplicated on tab 1 (Input MUX) for quick access.
NOTE: The software does not allow for simultaneous GPIO, Test DAC, IDAC, or VBIAS functions to
be enabled on the same pin.
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Tab 5: GPIO
Tab 5, shown in Figure 21, controls the GPIO functions available on the AIN3-AIN9 and AINCOM pins.
The GPIO Functions controls select the GPIO direction and logic value. Note that the GPIO logic levels
are referenced to the analog supply voltage (5V-logic). The Value radio buttons serve dual purposes as
both controls and indicators. Value indicates the logic value when configured as an input, and controls the
logic value when configured as an output. The Value buttons are grayed out until the GPIO function is
enabled on the respective channel. Controlling the GPIO value does nothing when configured as an input.
5 GPIO
Figure 21. Tab 5 Settings
Clicking Read GPIO or modifying any of controls on this tab reads the GPIODAT register and updates all
value indicators.
NOTE: The GPIODAT register bits corresponding to GPIO inputs are read-only, and the GPIODAT
register bits corresponding to GPIO outputs are write-only. Therefore, you cannot read back
any GPIO output values from the GPIODAT register.
Store a copy of the GPIODAT register settings in memory (as this software does) in order to
recall the GPIO output configuration from memory.
NOTE: The software does not allow for simultaneous GPIO, Test DAC, IDAC, or VBIAS functions to
be enabled on the same pin.
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3.4.6
Tab 6: Test DAC
The Test DAC tab, as shown in Figure 20, controls the internal test DAC and is used to verify ADC
functionality by providing a known dc input voltage. The test DAC has two resistor divider taps that select
a fraction of the supply voltage. To use the test DAC, first select the Pos. Test Signal Supply Ratio and
Neg. Test Signal Supply Ratio settings, and then connect the test DAC to ADC1, ADC2, or both, with the
Test DAC to ADCx controls or with the MUX controls on tab 1 (Input MUX). Additionally, the test DAC
voltages are provided as outputs on pins AIN6 and AIN7 to be measured externally.
6 Test DAC
Figure 22. Tab 6 Settings
The Test DAC Calculator is provided to calculate the test DAC output and ADC input voltages based on
the supply ratios, AVDD, AVSS, and PGA gain settings. As an example, using the following settings:
• Pos. Test Signal Supply Ratio = 0.525
• Neg. Test Signal Supply Ratio = 0.475
• Test DAC to ADC1 = Input to ADC1 (to select the Test DAC as the input source for ADC1)
• PGA1 Gain = 1 V/V (on tab 1)
For a supply voltage of 5 V (AVDD – AVSS), the test DAC outputs (5 V) × (0.525 V – 0.475 V) × (1 V/V) =
0.25 V to ADC1.
To output or measure the test DAC voltage externally, set the Test Signal Outputs drop-down menu to
Connected to AIN6/AIN7.
NOTE: The test DAC is susceptible to power supply noise. Allow a sufficient margin of error when
verifying ADC conversion results with the test DAC.
Create a ratiometric measurement of the test DAC by selecting the analog supply as the
voltage reference source for the ADC. Then the matching input and reference noise cancels
in the ADC conversion result.
NOTE: The software does not allow for simultaneous GPIO, Test DAC, IDAC, or VBIAS functions to
be enabled on the same pin.
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Tab 7: Data \ MODE (ADS1263 only)
Use tab 7, as shown in Figure 23, to enable or disable ADC2 data collection, and select whether ADC1 or
ADC2 data are displayed in the test plugin. This tab is only visible when the ADS1263EVM is connected.
7 Data \ MODE
Figure 23. Tab 7 Settings
To start ADC2 conversions and read back data from ADC2, Data Collection Mode must be set to ADC1 +
ADC2. This setting enables the ADC Data to Test Plug-in control. The ADC Data to Test Plug-in controls
whether data from ADC1 or ADC2 appear in the test plugin for evaluation.
ADC1 and ADC2 data do not have the same LSB size and likely contain different sample sizes; therefore,
the software is only able to evaluate one data set at a time. If ADC1 is selected in the ADC Data to Test
Plug-in section, ADC1 data appear in the test plugin panel to the right, and the ADCx Data graph displays
data from ADC2. Conversely, if ADC2 is selected in the ADC Data to Test Plug-in control, ADC2 data
appear in the test plugin panel, and ADC1 data appear in the ADCx Data graph. However, it is possible to
switch between ADC1 and ADC2 data sets in the test plugin without having to reacquire new data. After
acquiring ADC1 and ADC2 data (with Data Collection Mode set to ADC1 + ADC2), switch ADC Data to
Test Plug-in to the other ADC. A button with the text Swap EVM & Test Plugin Data? appears. Click the
Swap EVM & Test Plugin Data? button and then click Acquire. This procedure takes the existing ADC
data sets and swaps them between the ADCx Data graph and the test plugin.
NOTE: In ADCPro, when Data Collection Mode is set to ADC1 + ADC2, the data rate for ADC1
must be greater than or equal to two times the ADC2 data rate.
The firmware must poll the STATUS byte for new ADC2 data every time new ADC1 data are
ready. ADC1 data are ready when the DRDY signal goes low, but there is no DRDY signal to
indicate that new ADC2 is ready. As a result of this behavior, ADC2 data are lost if this
requirement is not satisfied.
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3.4.8
Tab 8: Calibration
Tab 8 (shown in Figure 24) allows for reading and writing of the offset and full-scale (gain) calibration
registers. The ADC2 offset and gain calibration registers are only available when the ADS1263EVM is
connected.
8 Calibration
Figure 24. Tab 8: Register Map
Program the calibration coefficients manually into the registers, or send the corresponding SPI calibration
command. Click an SPI command button to run the selected calibration routine. During a calibration
routine, CAL in Progress? lights up to show that the calibration process is ongoing. If the calibration
completes successfully, CAL Completed? lights up. If CAL Completed? does not light up, run the
calibration again.
The calibration coefficients are converted to their practical units in the Offset and Gain indicators. Note
that the units of Offset can be changed from uV to mV as needed.
Calibration is not required; however, calibration improves overall ADC accuracy by about an order of
magnitude.
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Tab 9: Register Map
Use tab 9 (shown in Figure 25) to read and display the current ADS126x register settings. This tab is
useful to see how device settings in the ADCPro software are stored in the ADS126x device registers.
9 Register Map
Figure 25. Tab 9: Register Map
Reading back the ADC registers is recommended in all applications to make sure that the ADC settings
are correct and match software assumptions. When the Register Map tab is selected or the Refresh
Register Map button is clicked; all the device registers are read, the Register Map table is updated, and all
ADC controls (on all tabs) are updated. The RESET button reverts all register settings back to the ADCPro
nominal values.
NOTE: The RESET button reverts all ADS126x register settings to a nominal state, as determined
by ADCPro. This nominal state programs the MODE0, MODE1, MODE2, and ADC2CFG
(when applicable) registers to nondefault ADS126x values (indicated by asterisks in the
register map table).
To revert all register settings back to the true ADS126x default values, use the RESET pin
control button on tab 10 (Extras / About).
Device settings such as the conversion control and STATUS/CRC byte configurations are
enforced by software to ensure proper communication between hardware and firmware.
The power-on reset (POR) function is also helpful in verifying correct device operation. The POR button,
at the bottom of this tab, displays the current value of the POR bit in the POWER register. When clicked,
the POR button toggles the value of the POR bit.
Save the register settings to a text file with the Save to File button. Recall register settings with the Load
from File button. Use this register map text file to document a particular setup. Reference this text file
during development or support on the E2E™ Precision Data Converter Forum.
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3.4.10
Tab 10: Extra / About
Tab 10 (Figure 26) is the last page with several useful controls.
10 Extras / About
Figure 26. Tab 10: Extras / About
The Documentation section of this tab provides quick access to support documents. Product Page, Data
Sheet, and User's Guide connect to the latest online documentation. Schematic opens a local copy of the
ADS126xEVM schematic.
The Pin Controls section is used to control the RESET/PWDN and START pin logic levels. Clicking on any
of these buttons toggles the logic levels, with the exception of the RESET button. The RESET button
pulses the RESET/PWDN pin and resets all register settings back to their default values.
The Software INFO section provides additional information about the software and hardware, as well as
some other useful diagnostic tools.
• Acquire Alert is a programmable acquisition-time alert. A pop up alerts the user when a data
acquisition is estimated to take longer than the programmed alert value. The pop up notifies the user of
the estimated acquisition time and provides the option to continue or cancel the acquisition. Cancelling
an acquisition in progress requires resetting the hardware and reloading the EVM plugin. Long
acquisition periods are possible because of the very low data rates of the ADS126x and large
allowable block sizes in ADCPro.
• Collection Info shows information about the number of samples collected from ADC1 and ADC2. If
data acquisition seems to be taking longer than expected, check that the actual number of samples
being collected accounts for the additional time. The number is slightly larger than the block size
requested in the test plugin. Reduce the number of samples or increase the ADC data rates to reduce
acquisition time. The acquisition time may be longer than the total number of samples divided by the
data rate because the data is first collected into MMB0 memory, then transferred to ADCPro using
USB, and finally processed in ADCPro before it is displayed.
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•
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View Data reveals a data monitor that shows the raw ADC codes along with the STATUS and
CHECKSUM/CRC bytes, as shown in Figure 27.
Figure 27. Data Monitor Window
•
View Errors reveals a STATUS byte error indicator that ORs all of the STATUS byte error flags to
check if any errors occurred in the previous acquisition, as shown in Figure 28. This window
automatically appears when an error flag is found in the acquired data set. Switching to the View Data
window is useful to see when this error first appeared in the collected data.
Figure 28. Status Byte Error Pop-up
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ADS126xEVM Schematic and Bill of Materials
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4
ADS126xEVM Schematic and Bill of Materials
A complete schematic for the ADS126xEVM is appended to this user's guide. The bill of materials is
provided in Table 5. Gerber files are available on request. Please email [email protected] or visit the E2E
Community Forums and ask for details on how to receive the files.
4.1
Bill of Materials
NOTE: All components should be compliant with the European Union Restriction on Use of
Hazardous Substances (RoHS) Directive. Some part numbers may be either leaded or
RoHS. Verify that purchased components are RoHS-compliant. (For more information about
TI's position on RoHS compliance, see the http://www.ti.com.)
Table 5. ADS126xEVM Bill of Materials
(1)
Item No.
Qty
1
11
2
9
3
Value
Ref Des
Description
Manufacturer
Part Number
-5V Input,
PC TEST POINT MINIATURE SMT
AINCOM, AVDD,
AVSS, DVDD,
GND, GND, GND,
IN0, IN1, REFOUT
Keystone
Electronics
5015
47 pF
C1, C4, C7, C11,
C16, C21-23, C26
CAP, CERM, 47 pF, 50V, NP0, 1%, 0603
TDK
C1608C0G1H470F080AA
5 (1)
NI
C2, C8, C17, C24,
C35
CAP, NI, X2Y
4
5
0.1 uF
C3, C9, C18, C25,
C36
CAP, CERM, 100 nF, 50V, NP0, +/-5%,
1206
TDK
C3216C0G1H104J160AA
5
1
4,700 pF
C5
CAP, CERM, 4.7 nF, 50V, NP0, 5%, 0603
TDK
C1608C0G1H472J080AA
6
6
1 uF
C6, C10, C12,
C13, C27, C32
CAP, CERM, 1 uF, 16V, X7R +/-10%, 0603
TDK
C1608X7R1C105K080AC
7
2
33 pF
C14, C15
CAP, CERM, 33 pF, 50V, NP0, +/-5%, 0402
Yageo
CC0402JRNPO9BN330
8
2
10,000 pF
C19, C20
CAP, CERM, 0.01 uF, 50V, X7R, +/-10%,
0402
Yageo
CC0402KRX7R9BB103
9
2
0.1 uF
C28, C33
CAP, CERM, 100 nF, 50V, X7R +/-10%,
0603
TDK
C1608X7R1H104K
10
3
10 uF
C29-31
CAP, CERM, 10 uF, 16V, X7R +/-20%, 1206 TDK
C3216X7R1C106M
11
2
1,000 pF
C34, C37
CAP, CERM, 1 nF, 100V, NP0, 1%, 0603
TDK
C1608C0G2A102F080AA
12
1
D1
DIODE, ZENER, 6.2V, 500mW, SOD-123
Diodes Inc.
DDZ6V2B-7
13
1
J1 (TOP SIDE)
HEADER, 20POS 10x2, 100mil, SMD,
GOLD
Samtec
TSM-110-01-L-DV-P
14
2
J1 (BOTTOM
SIDE), J3
CONN, FEMALE, 20POS DL, 100mil, SMD,
GOLD
Samtec
SSW-105-22-F-D-VS-K
15
1
J2
TERMINAL BLOCK, 3.5MM, 10POS, PCB
On Shore
Technology
ED555/10DS
16
1
J4
TERMINAL BLOCK, 3.5MM, 2POS, PCB
On Shore
Technology
ED555/2DS
17
1
J5 (TOP SIDE)
CONN, HEADER, 10POS 5x2, 100mil, SMT,
GOLD
Samtec
TSM-105-01-L-DV-P
18
1
J5 (BOTTOM
SIDE)
CONN, RECPT, 10POS, 100mil, SMT,
GOLD
Samtec
SSW-105-22-F-D-VS-K
19
4
JP1, JP2, JP3,
JP5 (ALL TOP
SIDE)
CONN, HEADER, 2POS, 100mil, T/H,
GOLD
Samtec
HTSW-102-07-G-S
20
1
JP4
CONN, HEADER, 6POS, 100mil DBL, SMD,
GOLD
Samtec
TSM-103-01-L-DV-P
21
14
47 Ohms
R1, R6-9, R11-16,
R18, R20, R21
RES, 47 Ohm, 1%, 1/10W, 0603
Panasonic
ERJ-3EKF47R0V
22
6 (1)
NI
R2, R10, R22,
R24, R27, R31
RES, NI, 0603
23
3
100 kOhms
R3-5
RES, 100k Ohm, 5%, 1/10W, 0603
Panasonic
ERJ-3GEYJ104V
24
1
3.9 kOhms
R17
RES, 3.9K Ohm, 1/10W, 0.05%, 0603
Susumu
RG1608N-392-W-T1
This component is not installed.
SBAU206 – April 2015
Submit Documentation Feedback
ADS126xEVM-PDK
Copyright © 2015, Texas Instruments Incorporated
31
ADS126xEVM Schematic and Bill of Materials
www.ti.com
Table 5. ADS126xEVM Bill of Materials (continued)
Item No.
Qty
Value
25
1
620 Ohms
R19
RES, 620 Ohm, 0.11%, 1/10W, 0603
Panasonic
ERA-3APB621V
26
1
12 kOhms
R23
RES, 12k Ohm, 0.1%, 1/16W, 0603
TE Connectivity
7-1676481-8
27
1
1.2 kOhms
R25
RES, 1.2K Ohm, 1/10W, 0.1%, 0603
Panasonic
ERA-3ARB122V
28
2
499 Ohms
R26, R28
RES, 499 Ohm, 0.1%, 1/10W, 0603
Panasonic
ERA-3AEB4990V
29
2
2.7 kOhms
R29, R30
RES, 2.7k Ohm, 5%, 1/10W, 0603
Panasonic
ERJ-3GEYJ272V
30
1
0 Ohms
R32
RES, 0 Ohm, 1/10W, 0603
Panasonic
ERJ-3GEY0R00V
31
1
2.2k @ 25°C
RT1
Thermistor NTC, 2.2k Ohm, 1%, 0805
Vishay
NTCS0805E3222FMT
32
1
S1
SWITCH, SLIDE, SPDT, GULLWING
Copal Electronics
CAS-120TB
33
1
S2
SWITCH, SLIDE, DPDT, GULLWING
Copal Electronics
CAS-220TB
34
7
SH-J1, SH-J2, SH- SHUNT, 100mil, GOLD, BLACK
J3, SH-J4, SH-J5
3M
969102-0000-DA
35
1
U1
IC, ADC, Delta-Sigma, 32-bit, 38kSPS
Texas Instruments
ADS1262IPW (2)
36
1
U2
IC, REG, LDO, 2.5V, 100mA, SOT23-5
Texas Instruments
TPS79225DBVT
37
1
U3
IC, REG, LDO, -2.5V, 0.2A, SOT23-5
Texas Instruments
TPS72325DBVT
38
1
U4
IC, EEPROM, 256 kBIT, 400 kHz, 8TSSOP
Microchip
Technology
24AA256-I/ST
39
1
X1
CRYSTAL, 7.3728 MHz, 18 pF, T/H
ECS Inc.
ECS-73-18-10X
(2)
32
Ref Des
Description
Manufacturer
Part Number
Installed for the ADS1262EVM. The ADS1263IPW is installed for the ADS1263EVM.
ADS126xEVM-PDK
SBAU206 – April 2015
Submit Documentation Feedback
Copyright © 2015, Texas Instruments Incorporated
1
2
3
4
COR1
R1
PIR101
47
PIR102
PIR202COR2
R2
NI
GND
PIR201
COJ2
J2
NLIN1
IN1
COR6
R6 47
PIR602
1
PIJ201
IN0
PI N201 PIR601
2
PIJ202
IN1
COIN2
IN2
3
PIJ203
IN2
4
PIJ204
IN3
5
PIJ205
IN4
PIJ206
6
IN5
PIR10COR10
2
R10
7
PIJ207
IN6
NI
8
PIJ208
IN7
9
PIJ209
AINCOM
NLIN2
IN2
X2Y Capacitor
COC2
C2 PIC20A NI
AIN1
(EXT REF1 N)
X2Y Capacitor
COC8
C8 PIC80A NI
NLREFOUT
REFOUT
GND
PIC1 01 47pF
COC10 PIC1001
C10
1uF PIC1002
AIN3
(EXT REF2 N)
PIR1202
START
Ratiometric
Connection
Jumper
1 IN6
2 IN4
PIJP102
1
IN0
2
IN1
3
IN2
PIJ301
B
PIJ302
PIJ303
4
IN3
5
IN4
PIJ304
PIJ305
6
PIJ306
IN5
7
PIJ307
IN6
8
PIJ308
IN7
COR17
R17
3.9k
R17 sets up a 1.95V reference
voltage with 500uA IDAC
NLIN5
IN5
PIR1902
PIA NCOM10
10
620
PIR1901
AINCOM
COC22
C22 PIC2201
47pF PIC2202
11
12
8PIU108
REFOUT
21
AIN0 PIU1021
NLAIN0
AIN0
9PIU109
START
12PIU1012
14PIU1014
SCLK
DGND
PIU101818
17
BYPASS PIU1017
DIN
COR20
R20 47
PIR2002
GND
5
PIJ105
NL\CS
CS
COC23
C23
17
PIJ3017
PIC2601
GND
NLIN7
IN7
COR21
R21 47
PIR2101
18
GND
PIREFOUT10
CM f-3dB = 72 MHz
DM f-3dB = 16.9 kHz
REFOUT
COX1
X1
COS1
S1
PIC1402
CAS-120TB
Clock Select
Switch
t° RT1
GND
SDA
GND
20
PIJ1020
INT/EXT Clock
Jumper
AVDD
B
DAUGHTER-SERIAL
Top and Bottom Side
(Bottom Connects to MMB0)
5
PIS205
3
4
PIS204
GND
1
Positive Supply
1
COU2
U2
PIC2701
PIC2702
3
PIU203
IN
EN
DVDD
COAVSS
AVSS
PIAVD 01
PIJP402
3
PIJP403
CODVDD
DVDD
PIAVS 01
4
PIJP404
5
Negative Supply
PIDVD 01
6
PIJP405
PIJP406
COJP4
JP4
+3.3V
CAS-220TB
1
PIU201
2
PIJP401
2
PIS201
+5V
AVSS
COAVDD
AVDD
PIS203
Pos 1
Power Measurement
or EXT Supply Jumpers
+2.5V
5
OUT PIU205
4
BYP PIU204
2
GND PIU202
TPS79225DBVT
PIC2802
PIC2801
COC28
C28
100nF
GND
COU3
U3
-5V
2
PIU302
COC32
C32
1uF
NI
PIC3201
3
PIU303
PIC320
COR26
R26 499
PIR2602
AVDD
AVSS
PIC2901
PIC2902
PIC30 1
PIC30 2
COC29
C29
10uF
COC30
C30
10uF
DVDD
PIC3101
COC31
C31
PIC3102 10uF
C
AVDD
PID102
PID101
COD1
D1
DDZ6V2B-7
2
PIJ402
COR28 499
PIR2801
R28
PIR2802
PIR3102
EN
-2.5V
5
OUT PIU305
4
BYP PIU304
1
GND
PIU301
GND
GND
GND
AVSS
PIC3 02 C33
COC33
PIC3 01 100nF
AIN8
PIR2601
GND
IN
TPS72325DBVT
X2Y Capacitor
PIC3401 COC34
C34
PIC3402 1nF
PIC3701 COC37
C37
PIC3702 1nF
PIC3602
PIC3601
COC36
C36
100nF
GND
COC35
C35PIC350A NI
GND
COGND1
GND1
GND
PIC350G
PIC350B
GND
+3.3V
COGND2
GND2
PIGND101
PIGND201
GND
GND
PIR2702
COR27
R27
AIN9
NI
PIR2701
COU4
U4
1
A0
2
3
PIU403 A2
4
PIU404
VSS
PIU401
COR31
R31
FILTERING
NI
CM f-3dB = 319 kHz
DM f-3dB = 1.59 kHz
PIR3101
GND3
COGND3
1
2
Sensor Bias
Jumper
PIJP501
PIJP502
AINCOM
COJP5
JP5
1
19
PIJ1019
GND
(-5V Supply must be supplied by user)
GND
GND
18
PIJP202
GND
PIC240B
IN7
PIR2401
Cold Junction = GND
PIGND301
17
2
PIJ1018
COS2
S2
2
MMB0 Signals
Signal Pin #
+VA
1
-VA
2
+5VA
3
-5VA
4
DGND
5
AGND
6
+1.8VD
7
VD1
8
+3.3VD
9
+5VD
10
+5V
PIR3202
COR32
R32
0
+3.3V
PI05V Input01
PIJ501 PIJ502 PIJ503 PIJ504 PIJ50 PIJ506 PIJ507 PIJ508 PIJ509 PIJ501
Top and Bottom Side
(Bottom Connects to MMB0)
J5
COJ5
3
DAUGHTER-POWER
PIR3201
PIU402 A1
PIR2902
8
VCC PIU408
7
WP PIU407
6
SCL PIU406
5
SDA PIU405
PIR2901
COR29
R29
2.7k
PIR3002
COR30
R30
2.7k
PIR3001
NLSCL
SCL
NLSDA
SDA
D
24AA256-I/ST
EEPROM
GND (Used by MMB0 only) GND
-5V
CO05V
Input
-5V Input
1
2
3
4
5
6
7
8
9
10
D
16
PIJ1016
PIJ1017
IN6
GND
ED555/2DS
TERMINAL BLOCK
Top Side
15
PIJ1015
SCL
COC15
C15
PIC1501 33pF
PIR2202
PIR2402
1
PIJ401
COR15 47
R15
PIR1502
PIC1502
COC14
C14
PIC1401 33pF
3 PIJP201
1
PIS103
GND
PIR2501
Thermocouple
Input
PIR1501
13
PIJ1013
14
PIJ1014
ECS-73-18-10X
PIX102
COJP2
JP2
Pos 2
COR23
R23 NI
12k
R24
COR24
COJ4
J4
NL\DRDY
DRDY
COR14 47
PIR1402
Supply Polarity
Switch
GND
PIR2502
R14
PIR1401
1
MMB0 passes signals through to J10
Configured for 250uA IDAC
in single supply configuration COR25
R25
(Install 0-Ohms in R22 & R24) 1.2k
NLDOUT0D\R\D\Y\
DOUT/DRDY
11
PIJ1011
12
GND
COC27
C27
1uF
PIR2302
COR13 47
R13
PIR1302
+5V
AIN7
(Test SIG N)
20
PIRT102
PIR1301
PIJ1012
GND
PIS202
19
PIR2201
9
10
PIJ1010
NLDIN
DIN
6
PIS206
PIC240G
PIR2102
PIJ3019
PIR2301
MMB0 Signals
Signal Pin #
CNTL
1
GPIO0
2
CLKX
3
DGND
4
CLKR
5
GPIO1
6
FSX
7
GPIO2
8
FSR
9
DGND
10
DX
11
GPIO3
12
DR
13
GPIO4
14
*INT
15
SCL
16
TOUT
17
DGND
18
GPIO5
19
SDA
20
7
PIJ107
PIX101
47pF
INPUT FILTERING
CORT1PIRT10
6
PIJ106
PIJ109
PIC1301 COC13
C13
PIC1302 1uF
X2Y Capacitor
COC24
C24 PIC240A NI
COC25
C25
GND
100nF
COREFOUT1
REFOUT1
Thermistor (for CJC)
2.2k @ 25°C
NL\RESET0PWDN R9
COR9 47
RESET/PWDN
PIR901
PIR902
COR11 47
R11
PIR1101
PIR1102
8
PIJ108
COC12 PIC1201
C12
1uF PIC1202
2
COC19
COC20
C19 PIC1901
C20 PIC2001
0.01uF PIC1902 0.01uF PIC2002
3
PIJ103
DVDD
AVSS
AIN6
(Test SIG P)
16
PIJ3016
COR22
R22
COR7 47
R7
PIR701
PIR702
4
PIJ104
PIS102
AVDD
A
2
PIJ102
NLSCLK
SCLK
RESET/PWDN
15
XTAL1/CLKIN PIU1015
DRDY
COJ1
J1
1
16
XTAL2 PIU1016
DOUT/DRDY
PIR502
PIJ101
19
DVDD PIU1019
CS
PIR402
DIGITAL
PIR2001
PIC2302 47pFPIC2502
PIC2602 COC26
PIC2501
C26
DAUGHTER-ANALOG
Bottom Side
(Connects to MMB0)
NLAIN1
AIN1
AVSS
PIC2301
PIJ3020
NLAIN2
AIN2
20
RESET/PWDN PIU1020
PIR302
NLSTART
START
22
AIN1 PIU1022
AVSS Connection
Jumper
15
PIJ3015
C
NLAIN3
AIN3
PIR501
GND
13
PIJ3013
PIJ3018
24
AIN3 PIU1024
PIR401
COR3 R4
COR4 R5
COR5
R3
100k 100k 100k
R19 increases REF3N voltage to >0.3V when used with
500uA IDAC in single supply and ratiometric configurations
NLIN6
IN6
PIJ3012
14
PIJ3014
NLAIN4
AIN4
AIN5
ADS126xIPW
AIN5
(EXT REF3 N)
PIR1802
25
AIN4 PIU1025
AINCOM
PIR301
COJP3
JP3
COR19
R19
COAINCOM1
AINCOM1
PIJ3010
PIC2101 47pF
COR18
R18 47
PIR1801
2
PIJP302
1
PIJP301
9
PIJ309
PIJ3011
GND
NLAIN5
AIN5
23
AIN2 PIU1023
11PIU1011
AIN4
PIR1701
NLAIN6
AIN6
26
PIU1026
DVDD
PIS101
(EXT REF3 P)
PIC1601 COC16
C16
X2Y Capacitor
COC17
C17 PIC170A NI
PIC1602 47pFPIC1802 COC18
C18
PIC170G
GND
GND
PIC2102 COC21
PIC1801 100nF
PIC170B
C21
PIR1702
27
AIN6 PIU1027
AVSS
10PIU1010
DRDY
COJ3
J3
AIN9
AVDD
SCLK
COJP1
JP1
COR16
R16 47
PIR1601
PIR1602
NLAIN7
AIN7
7PIU107
DOUT/DRDY13PIU1013
PIJP101
NLIN4
IN4
28
AIN7 PIU1028
6PIU106
CS
AVSS
DIN
GND
AIN8
4PIU104
CAPP
COC5
C5 PIC501
4.7nF PIC502 5PIU105
CAPN
PIC80B
COC11
C11
COR12
R12 47
PIR1201
AVSS
PIC80G
GND
3PIU103
COC6
C6 PIC601
1uF PIC602
AIN2
(EXT REF2 P)
PIC701
COC7
C7
PIC702 47pF PIC902 C9
COC9
PIC1 02
PIC901 100nF
PIR10 1
2PIU102
NLAINCOM
AINCOM
10
PIJ2010
ED555/10DS
TERMINAL BLOCK
Top Side
NLAIN9
AIN9
GND
47
PIR802
GND
1PIU101
PIC20B
AVDD
COR8
R8
PIR801
NLIN3
IN3
NLAIN8
AIN8
PIC20G
GND
100nF
PIC402
PIC301
COC4
C4
PIC401 47pF
COU1
U1
2
A
AIN0
(EXT REF1 P)
PIC101 COC1
C1
PIC10247pF PIC302 C3
COC3
1
PI N101
6
ANALOG
COIN1
IN1
NLIN0
IN0
5
Designed for:Public Release
Mod. Date:12/31/2014
Texas Instruments and/or its licensors do not warrant the accuracy or completeness of this
Project: ADS126xEVM
specification or any information contained therein. Texas Instruments and/or its licensors do not
Sheet Title: EVM Schematic
Sheet:1 of 1
warrant that this design will meet the specifications, will be suitable for your application or fit for
Size: B
Schematic: 6580279
Rev: A
any particular purpose, or will operate in an implementation. Texas Instruments and/or its
Assembly Variant:[No Variations]
licensors do not warrant that the design is production worthy. You should completely validate
File: ADS126xEVM_RevA1_Schematic.SchDoc
and test your design implementation to confirm the system functionality for your application.
Contact: http://www.ti.com/support
4
5
6
http://www.ti.com
© Texas Instruments 2014
STANDARD TERMS AND CONDITIONS FOR EVALUATION MODULES
1.
Delivery: TI delivers TI evaluation boards, kits, or modules, including any accompanying demonstration software, components, or
documentation (collectively, an “EVM” or “EVMs”) to the User (“User”) in accordance with the terms and conditions set forth herein.
Acceptance of the EVM is expressly subject to the following terms and conditions.
1.1 EVMs are intended solely for product or software developers for use in a research and development setting to facilitate feasibility
evaluation, experimentation, or scientific analysis of TI semiconductors products. EVMs have no direct function and are not
finished products. EVMs shall not be directly or indirectly assembled as a part or subassembly in any finished product. For
clarification, any software or software tools provided with the EVM (“Software”) shall not be subject to the terms and conditions
set forth herein but rather shall be subject to the applicable terms and conditions that accompany such Software
1.2 EVMs are not intended for consumer or household use. EVMs may not be sold, sublicensed, leased, rented, loaned, assigned,
or otherwise distributed for commercial purposes by Users, in whole or in part, or used in any finished product or production
system.
2
Limited Warranty and Related Remedies/Disclaimers:
2.1 These terms and conditions do not apply to Software. The warranty, if any, for Software is covered in the applicable Software
License Agreement.
2.2 TI warrants that the TI EVM will conform to TI's published specifications for ninety (90) days after the date TI delivers such EVM
to User. Notwithstanding the foregoing, TI shall not be liable for any defects that are caused by neglect, misuse or mistreatment
by an entity other than TI, including improper installation or testing, or for any EVMs that have been altered or modified in any
way by an entity other than TI. Moreover, TI shall not be liable for any defects that result from User's design, specifications or
instructions for such EVMs. Testing and other quality control techniques are used to the extent TI deems necessary or as
mandated by government requirements. TI does not test all parameters of each EVM.
2.3 If any EVM fails to conform to the warranty set forth above, TI's sole liability shall be at its option to repair or replace such EVM,
or credit User's account for such EVM. TI's liability under this warranty shall be limited to EVMs that are returned during the
warranty period to the address designated by TI and that are determined by TI not to conform to such warranty. If TI elects to
repair or replace such EVM, TI shall have a reasonable time to repair such EVM or provide replacements. Repaired EVMs shall
be warranted for the remainder of the original warranty period. Replaced EVMs shall be warranted for a new full ninety (90) day
warranty period.
3
Regulatory Notices:
3.1 United States
3.1.1
Notice applicable to EVMs not FCC-Approved:
This kit is designed to allow product developers to evaluate electronic components, circuitry, or software associated with the kit
to determine whether to incorporate such items in a finished product and software developers to write software applications for
use with the end product. This kit is not a finished product and when assembled may not be resold or otherwise marketed unless
all required FCC equipment authorizations are first obtained. Operation is subject to the condition that this product not cause
harmful interference to licensed radio stations and that this product accept harmful interference. Unless the assembled kit is
designed to operate under part 15, part 18 or part 95 of this chapter, the operator of the kit must operate under the authority of
an FCC license holder or must secure an experimental authorization under part 5 of this chapter.
3.1.2
For EVMs annotated as FCC – FEDERAL COMMUNICATIONS COMMISSION Part 15 Compliant:
CAUTION
This device complies with part 15 of the FCC Rules. Operation is subject to the following two conditions: (1) This device may not
cause harmful interference, and (2) this device must accept any interference received, including interference that may cause
undesired operation.
Changes or modifications not expressly approved by the party responsible for compliance could void the user's authority to
operate the equipment.
FCC Interference Statement for Class A EVM devices
NOTE: This equipment has been tested and found to comply with the limits for a Class A digital device, pursuant to part 15 of
the FCC Rules. These limits are designed to provide reasonable protection against harmful interference when the equipment is
operated in a commercial environment. This equipment generates, uses, and can radiate radio frequency energy and, if not
installed and used in accordance with the instruction manual, may cause harmful interference to radio communications.
Operation of this equipment in a residential area is likely to cause harmful interference in which case the user will be required to
correct the interference at his own expense.
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FCC Interference Statement for Class B EVM devices
NOTE: This equipment has been tested and found to comply with the limits for a Class B digital device, pursuant to part 15 of
the FCC Rules. These limits are designed to provide reasonable protection against harmful interference in a residential
installation. This equipment generates, uses and can radiate radio frequency energy and, if not installed and used in accordance
with the instructions, may cause harmful interference to radio communications. However, there is no guarantee that interference
will not occur in a particular installation. If this equipment does cause harmful interference to radio or television reception, which
can be determined by turning the equipment off and on, the user is encouraged to try to correct the interference by one or more
of the following measures:
•
•
•
•
Reorient or relocate the receiving antenna.
Increase the separation between the equipment and receiver.
Connect the equipment into an outlet on a circuit different from that to which the receiver is connected.
Consult the dealer or an experienced radio/TV technician for help.
3.2 Canada
3.2.1
For EVMs issued with an Industry Canada Certificate of Conformance to RSS-210
Concerning EVMs Including Radio Transmitters:
This device complies with Industry Canada license-exempt RSS standard(s). Operation is subject to the following two conditions:
(1) this device may not cause interference, and (2) this device must accept any interference, including interference that may
cause undesired operation of the device.
Concernant les EVMs avec appareils radio:
Le présent appareil est conforme aux CNR d'Industrie Canada applicables aux appareils radio exempts de licence. L'exploitation
est autorisée aux deux conditions suivantes: (1) l'appareil ne doit pas produire de brouillage, et (2) l'utilisateur de l'appareil doit
accepter tout brouillage radioélectrique subi, même si le brouillage est susceptible d'en compromettre le fonctionnement.
Concerning EVMs Including Detachable Antennas:
Under Industry Canada regulations, this radio transmitter may only operate using an antenna of a type and maximum (or lesser)
gain approved for the transmitter by Industry Canada. To reduce potential radio interference to other users, the antenna type
and its gain should be so chosen that the equivalent isotropically radiated power (e.i.r.p.) is not more than that necessary for
successful communication. This radio transmitter has been approved by Industry Canada to operate with the antenna types
listed in the user guide with the maximum permissible gain and required antenna impedance for each antenna type indicated.
Antenna types not included in this list, having a gain greater than the maximum gain indicated for that type, are strictly prohibited
for use with this device.
Concernant les EVMs avec antennes détachables
Conformément à la réglementation d'Industrie Canada, le présent émetteur radio peut fonctionner avec une antenne d'un type et
d'un gain maximal (ou inférieur) approuvé pour l'émetteur par Industrie Canada. Dans le but de réduire les risques de brouillage
radioélectrique à l'intention des autres utilisateurs, il faut choisir le type d'antenne et son gain de sorte que la puissance isotrope
rayonnée équivalente (p.i.r.e.) ne dépasse pas l'intensité nécessaire à l'établissement d'une communication satisfaisante. Le
présent émetteur radio a été approuvé par Industrie Canada pour fonctionner avec les types d'antenne énumérés dans le
manuel d’usage et ayant un gain admissible maximal et l'impédance requise pour chaque type d'antenne. Les types d'antenne
non inclus dans cette liste, ou dont le gain est supérieur au gain maximal indiqué, sont strictement interdits pour l'exploitation de
l'émetteur
3.3 Japan
3.3.1
Notice for EVMs delivered in Japan: Please see http://www.tij.co.jp/lsds/ti_ja/general/eStore/notice_01.page 日本国内に
輸入される評価用キット、ボードについては、次のところをご覧ください。
http://www.tij.co.jp/lsds/ti_ja/general/eStore/notice_01.page
3.3.2
Notice for Users of EVMs Considered “Radio Frequency Products” in Japan: EVMs entering Japan may not be certified
by TI as conforming to Technical Regulations of Radio Law of Japan.
If User uses EVMs in Japan, not certified to Technical Regulations of Radio Law of Japan, User is required by Radio Law of
Japan to follow the instructions below with respect to EVMs:
1.
2.
3.
Use EVMs in a shielded room or any other test facility as defined in the notification #173 issued by Ministry of Internal
Affairs and Communications on March 28, 2006, based on Sub-section 1.1 of Article 6 of the Ministry’s Rule for
Enforcement of Radio Law of Japan,
Use EVMs only after User obtains the license of Test Radio Station as provided in Radio Law of Japan with respect to
EVMs, or
Use of EVMs only after User obtains the Technical Regulations Conformity Certification as provided in Radio Law of Japan
with respect to EVMs. Also, do not transfer EVMs, unless User gives the same notice above to the transferee. Please note
that if User does not follow the instructions above, User will be subject to penalties of Radio Law of Japan.
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【無線電波を送信する製品の開発キットをお使いになる際の注意事項】開発キットの中には技術基準適合証明を受けて
いないものがあります。技術適合証明を受けていないもののご使用に際しては、電波法遵守のため、以下のいずれかの
措置を取っていただく必要がありますのでご注意ください。
1.
2.
3.
電波法施行規則第6条第1項第1号に基づく平成18年3月28日総務省告示第173号で定められた電波暗室等の試験設備でご使用
いただく。
実験局の免許を取得後ご使用いただく。
技術基準適合証明を取得後ご使用いただく。
なお、本製品は、上記の「ご使用にあたっての注意」を譲渡先、移転先に通知しない限り、譲渡、移転できないものとします。
上記を遵守頂けない場合は、電波法の罰則が適用される可能性があることをご留意ください。日本テキサス・イ
ンスツルメンツ株式会社
東京都新宿区西新宿６丁目２４番１号
西新宿三井ビル
3.3.3
Notice for EVMs for Power Line Communication: Please see http://www.tij.co.jp/lsds/ti_ja/general/eStore/notice_02.page
電力線搬送波通信についての開発キットをお使いになる際の注意事項については、次のところをご覧くださ
い。http://www.tij.co.jp/lsds/ti_ja/general/eStore/notice_02.page
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4
EVM Use Restrictions and Warnings:
4.1 EVMS ARE NOT FOR USE IN FUNCTIONAL SAFETY AND/OR SAFETY CRITICAL EVALUATIONS, INCLUDING BUT NOT
LIMITED TO EVALUATIONS OF LIFE SUPPORT APPLICATIONS.
4.2 User must read and apply the user guide and other available documentation provided by TI regarding the EVM prior to handling
or using the EVM, including without limitation any warning or restriction notices. The notices contain important safety information
related to, for example, temperatures and voltages.
4.3 Safety-Related Warnings and Restrictions:
4.3.1
User shall operate the EVM within TI’s recommended specifications and environmental considerations stated in the user
guide, other available documentation provided by TI, and any other applicable requirements and employ reasonable and
customary safeguards. Exceeding the specified performance ratings and specifications (including but not limited to input
and output voltage, current, power, and environmental ranges) for the EVM may cause personal injury or death, or
property damage. If there are questions concerning performance ratings and specifications, User should contact a TI
field representative prior to connecting interface electronics including input power and intended loads. Any loads applied
outside of the specified output range may also result in unintended and/or inaccurate operation and/or possible
permanent damage to the EVM and/or interface electronics. Please consult the EVM user guide prior to connecting any
load to the EVM output. If there is uncertainty as to the load specification, please contact a TI field representative.
During normal operation, even with the inputs and outputs kept within the specified allowable ranges, some circuit
components may have elevated case temperatures. These components include but are not limited to linear regulators,
switching transistors, pass transistors, current sense resistors, and heat sinks, which can be identified using the
information in the associated documentation. When working with the EVM, please be aware that the EVM may become
very warm.
4.3.2
EVMs are intended solely for use by technically qualified, professional electronics experts who are familiar with the
dangers and application risks associated with handling electrical mechanical components, systems, and subsystems.
User assumes all responsibility and liability for proper and safe handling and use of the EVM by User or its employees,
affiliates, contractors or designees. User assumes all responsibility and liability to ensure that any interfaces (electronic
and/or mechanical) between the EVM and any human body are designed with suitable isolation and means to safely
limit accessible leakage currents to minimize the risk of electrical shock hazard. User assumes all responsibility and
liability for any improper or unsafe handling or use of the EVM by User or its employees, affiliates, contractors or
designees.
4.4 User assumes all responsibility and liability to determine whether the EVM is subject to any applicable international, federal,
state, or local laws and regulations related to User’s handling and use of the EVM and, if applicable, User assumes all
responsibility and liability for compliance in all respects with such laws and regulations. User assumes all responsibility and
liability for proper disposal and recycling of the EVM consistent with all applicable international, federal, state, and local
requirements.
5.
Accuracy of Information: To the extent TI provides information on the availability and function of EVMs, TI attempts to be as accurate
as possible. However, TI does not warrant the accuracy of EVM descriptions, EVM availability or other information on its websites as
accurate, complete, reliable, current, or error-free.
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6.
Disclaimers:
6.1 EXCEPT AS SET FORTH ABOVE, EVMS AND ANY WRITTEN DESIGN MATERIALS PROVIDED WITH THE EVM (AND THE
DESIGN OF THE EVM ITSELF) ARE PROVIDED "AS IS" AND "WITH ALL FAULTS." TI DISCLAIMS ALL OTHER
WARRANTIES, EXPRESS OR IMPLIED, REGARDING SUCH ITEMS, INCLUDING BUT NOT LIMITED TO ANY IMPLIED
WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE OR NON-INFRINGEMENT OF ANY
THIRD PARTY PATENTS, COPYRIGHTS, TRADE SECRETS OR OTHER INTELLECTUAL PROPERTY RIGHTS.
6.2 EXCEPT FOR THE LIMITED RIGHT TO USE THE EVM SET FORTH HEREIN, NOTHING IN THESE TERMS AND
CONDITIONS SHALL BE CONSTRUED AS GRANTING OR CONFERRING ANY RIGHTS BY LICENSE, PATENT, OR ANY
OTHER INDUSTRIAL OR INTELLECTUAL PROPERTY RIGHT OF TI, ITS SUPPLIERS/LICENSORS OR ANY OTHER THIRD
PARTY, TO USE THE EVM IN ANY FINISHED END-USER OR READY-TO-USE FINAL PRODUCT, OR FOR ANY
INVENTION, DISCOVERY OR IMPROVEMENT MADE, CONCEIVED OR ACQUIRED PRIOR TO OR AFTER DELIVERY OF
THE EVM.
7.
USER'S INDEMNITY OBLIGATIONS AND REPRESENTATIONS. USER WILL DEFEND, INDEMNIFY AND HOLD TI, ITS
LICENSORS AND THEIR REPRESENTATIVES HARMLESS FROM AND AGAINST ANY AND ALL CLAIMS, DAMAGES, LOSSES,
EXPENSES, COSTS AND LIABILITIES (COLLECTIVELY, "CLAIMS") ARISING OUT OF OR IN CONNECTION WITH ANY
HANDLING OR USE OF THE EVM THAT IS NOT IN ACCORDANCE WITH THESE TERMS AND CONDITIONS. THIS OBLIGATION
SHALL APPLY WHETHER CLAIMS ARISE UNDER STATUTE, REGULATION, OR THE LAW OF TORT, CONTRACT OR ANY
OTHER LEGAL THEORY, AND EVEN IF THE EVM FAILS TO PERFORM AS DESCRIBED OR EXPECTED.
8.
Limitations on Damages and Liability:
8.1 General Limitations. IN NO EVENT SHALL TI BE LIABLE FOR ANY SPECIAL, COLLATERAL, INDIRECT, PUNITIVE,
INCIDENTAL, CONSEQUENTIAL, OR EXEMPLARY DAMAGES IN CONNECTION WITH OR ARISING OUT OF THESE
TERMS ANDCONDITIONS OR THE USE OF THE EVMS PROVIDED HEREUNDER, REGARDLESS OF WHETHER TI HAS
BEEN ADVISED OF THE POSSIBILITY OF SUCH DAMAGES. EXCLUDED DAMAGES INCLUDE, BUT ARE NOT LIMITED
TO, COST OF REMOVAL OR REINSTALLATION, ANCILLARY COSTS TO THE PROCUREMENT OF SUBSTITUTE GOODS
OR SERVICES, RETESTING, OUTSIDE COMPUTER TIME, LABOR COSTS, LOSS OF GOODWILL, LOSS OF PROFITS,
LOSS OF SAVINGS, LOSS OF USE, LOSS OF DATA, OR BUSINESS INTERRUPTION. NO CLAIM, SUIT OR ACTION SHALL
BE BROUGHT AGAINST TI MORE THAN ONE YEAR AFTER THE RELATED CAUSE OF ACTION HAS OCCURRED.
8.2 Specific Limitations. IN NO EVENT SHALL TI'S AGGREGATE LIABILITY FROM ANY WARRANTY OR OTHER OBLIGATION
ARISING OUT OF OR IN CONNECTION WITH THESE TERMS AND CONDITIONS, OR ANY USE OF ANY TI EVM
PROVIDED HEREUNDER, EXCEED THE TOTAL AMOUNT PAID TO TI FOR THE PARTICULAR UNITS SOLD UNDER
THESE TERMS AND CONDITIONS WITH RESPECT TO WHICH LOSSES OR DAMAGES ARE CLAIMED. THE EXISTENCE
OF MORE THAN ONE CLAIM AGAINST THE PARTICULAR UNITS SOLD TO USER UNDER THESE TERMS AND
CONDITIONS SHALL NOT ENLARGE OR EXTEND THIS LIMIT.
9.
Return Policy. Except as otherwise provided, TI does not offer any refunds, returns, or exchanges. Furthermore, no return of EVM(s)
will be accepted if the package has been opened and no return of the EVM(s) will be accepted if they are damaged or otherwise not in
a resalable condition. If User feels it has been incorrectly charged for the EVM(s) it ordered or that delivery violates the applicable
order, User should contact TI. All refunds will be made in full within thirty (30) working days from the return of the components(s),
excluding any postage or packaging costs.
10. Governing Law: These terms and conditions shall be governed by and interpreted in accordance with the laws of the State of Texas,
without reference to conflict-of-laws principles. User agrees that non-exclusive jurisdiction for any dispute arising out of or relating to
these terms and conditions lies within courts located in the State of Texas and consents to venue in Dallas County, Texas.
Notwithstanding the foregoing, any judgment may be enforced in any United States or foreign court, and TI may seek injunctive relief
in any United States or foreign court.
Mailing Address: Texas Instruments, Post Office Box 655303, Dallas, Texas 75265
Copyright © 2015, Texas Instruments Incorporated
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IMPORTANT NOTICE
Texas Instruments Incorporated and its subsidiaries (TI) reserve the right to make corrections, enhancements, improvements and other
changes to its semiconductor products and services per JESD46, latest issue, and to discontinue any product or service per JESD48, latest
issue. Buyers should obtain the latest relevant information before placing orders and should verify that such information is current and
complete. All semiconductor products (also referred to herein as “components”) are sold subject to TI’s terms and conditions of sale
supplied at the time of order acknowledgment.
TI warrants performance of its components to the specifications applicable at the time of sale, in accordance with the warranty in TI’s terms
and conditions of sale of semiconductor products. Testing and other quality control techniques are used to the extent TI deems necessary
to support this warranty. Except where mandated by applicable law, testing of all parameters of each component is not necessarily
performed.
TI assumes no liability for applications assistance or the design of Buyers’ products. Buyers are responsible for their products and
applications using TI components. To minimize the risks associated with Buyers’ products and applications, Buyers should provide
adequate design and operating safeguards.
TI does not warrant or represent that any license, either express or implied, is granted under any patent right, copyright, mask work right, or
other intellectual property right relating to any combination, machine, or process in which TI components or services are used. Information
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Reproduction of significant portions of TI information in TI data books or data sheets is permissible only if reproduction is without alteration
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Resale of TI components or services with statements different from or beyond the parameters stated by TI for that component or service
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Buyer acknowledges and agrees that it is solely responsible for compliance with all legal, regulatory and safety-related requirements
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In some cases, TI components may be promoted specifically to facilitate safety-related applications. With such components, TI’s goal is to
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requirements. Nonetheless, such components are subject to these terms.
No TI components are authorized for use in FDA Class III (or similar life-critical medical equipment) unless authorized officers of the parties
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Only those TI components which TI has specifically designated as military grade or “enhanced plastic” are designed and intended for use in
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Applications
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www.ti.com/audio
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www.ti.com/automotive
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amplifier.ti.com
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www.ti.com/communications
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www.ti.com/computers
DLP® Products
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