NI SCC-AI Series User manual
USER GUIDE
SCC-AI Series Isolated Analog
Input Modules
The SCC-AI Series isolated analog input modules can extract a relatively
low-amplitude input signal from a high-common-mode voltage so the
E/M Series DAQ device can measure the input signal. They also can
amplify and filter the input signal, resulting in higher measurement
resolution and accuracy.
SCC-AI Series modules are available in a range of gains from 0.2 to 200.
They contain lowpass filters of either 10 kHz or 4 Hz bandwidth. Table 1
gives the gain and bandwidth for each module.
Table 1. SCC-AI Module Input/Output Range, Gain, and Bandwidth
Model Input Range Output Range Gain Bandwidth
SCC-AI01 ±42 Vpk/VDC ±8.4 V 0.2 10 kHz
SCC-AI02 ±20 V ±10 V 0.5 10 kHz
SCC-AI03 ±10 V ±10 V 110 kHz
SCC-AI04 ±5 V ±10 V 210 kHz
SCC-AI05 ±1 V ±10 V 10 10 kHz
SCC-AI06 ±100 mV ±10 V 100 10 kHz
SCC-AI07 ±50 mV ±10 V 200 10 kHz
SCC-AI13 ±10 V ±10 V 14 Hz
SCC-AI14 ±5 V ±10 V 24 Hz
SCC-AI Series Isolated Analog Input Modules 2 ni.com
Conventions
The following conventions are used in this guide:
<> Angle brackets that contain numbers separated by an ellipsis represent
a range of values associated with a bit or signal name—for example,
AI <0..7>.
»The »symbol leads you through nested menu items and dialog box options
to a final action. The sequence File»Page Setup»Options directs you to
pull down the File menu, select the Page Setup item, and select Options
from the last dialog box.
This icon denotes a note, which alerts you to important information.
This icon denotes a caution, which advises you of precautions to take to
avoid injury, data loss, or a system crash. When this symbol is marked on
the product, refer to the Read Me First: Safety and Radio-Frequency
Interference document, shipped with the product, for precautions to take.
When symbol is marked on a product, it denotes a warning advising you to
take precautions to avoid electrical shock.
When symbol is marked on a product, it denotes a component that may be
hot. Touching this component may result in bodily injury.
bold Bold text denotes items that you must select in the software, such as menu
items and dialog box options. Bold text also denotes parameter names.
italic Italic text denotes variables, emphasis, a cross reference, or an introduction
to a key concept. Italic text also denotes text that is a placeholder for a word
or value that you must supply.
monospace Text in this font denotes text or characters that you should enter from the
keyboard, sections of code, programming examples, and syntax examples.
This font is also used for the proper names of disk drives, paths, directories,
programs, subprograms, subroutines, device names, functions, operations,
variables, filenames, and extensions.
SC-2345 SC-2345 refers to both the SC-2345 connector block and the SC-2345
configurable connector.
SCC SCC refers to any SCC series signal conditioning module.
SCC-AI SCC-AI refers to any isolated analog input module in the SCC-AI Series
unless otherwise noted.
©National Instruments Corporation 3 SCC-AI Series Isolated Analog Input Modules
What You Need to Get Started
To set up and use the SCC-AI, you need the following items:
❑Hardware
– SCC-68
or
– SC-2345/2350 with one of the following:
• SCC-PWR01
• SCC-PWR02 and the PS01 power supply
• SCC-PWR03 (requires a 7 to 42 VDC power supply,
not included)
– One or more SCC-AI
– 68-pin E/M Series DAQ device
– 68-pin cable
– Quick Reference Label
❑Software
– The latest version of NI-DAQmx
❑Documentation
–SCC-AI Series Isolated Analog Input Modules User Guide
–SC-2345/2350 User Manual
– SCC-68 User Guide
or
–SCC Quick Start Guide
–Read Me First: Safety and Radio-Frequency Interference
– Documentation for your hardware
– Documentation for your software
❑Tools
– 1/8 in. flathead screwdriver
– Numbers 1 and 2 Phillips screwdrivers
– Wire insulation stripper
Note Software scaling of measurements is not supported on the Macintosh operating
system. Refer to the SCC-AI Module Pin Assignments section.
SCC-AI Series Isolated Analog Input Modules 4 ni.com
You can download NI documents from ni.com/manuals. To download
the latest version of NI-DAQmx, click Download Software at ni.com.
Device Specific Information
Note For general SCC module installation and signal connection information, and
information about the SC-2345/2350 or SCC-68, refer to the SCC Quick Start Guide,
available for download at ni.com/manuals.
Installing the Module
Caution Refer to the Read Me First: Safety and Radio-Frequency Interference document
before removing equipment covers or connecting/disconnecting any signal wires.
You can plug the SCC-AI into any analog input socket on the
SC-2345/2350 or SCC-68. The socket you choose determines which
E/M Series DAQ device channels receive the SCC-AI signals.
For single-stage input conditioning, plug the SCC-AI into any slot of the
SC-68, or any socket of the SC-2345/2350 J(X+1), where Xis 0 to 7.
Connect the input signals to the module as described inthe Connecting the
Input Signals section.
If you use the SCC-AI in a dual-stage configuration in an SC-2345, the
SCC-AI must be the first-stage module. Plug it into any socket J(X+9) and
plug the second-stage SCC into socket J(X+1), where Xis 0 to 7. Connect
the input signals to the SCC-AIas described in the Connecting the Input
Signalssection. The SC-2345 connects the output signals of the first-stage
SCC to the inputs of the second-stage SCC. An example of dual-stage
conditioning is an SCC-AI02 followed by an SCC-FV01 frequency input
module.
Sockets J9 to J16 of the SC-2345 are also available for digital input/output
(DIO) conditioning or control. Refer to the SC-2345/2350 User Manual for
more information on configuring, connecting, and installing SCC modules.
Connecting the Input Signals
Note The signal names have changed. Refer to ni.com/info and enter rdtntg to
confirm the signal names.
Each screw terminal on the SCC-AI is labeled by pin number <1..4>. Pins 1
and 2 form a channel routed to E/M Series DAQ device channel X+8, and
pins 3 and 4 form a channel routed to the E/M Series DAQ device channel
X, where Xis 0 to 7 depending on the socket where you plug in the module.
©National Instruments Corporation 5 SCC-AI Series Isolated Analog Input Modules
The SCC-AI provides channel-to-ground and module-to-module isolation
only. It does not provide isolation between the two channels of the SCC-AI.
Because both channels must have the same reference voltage, pins 1 and 3
are connected together internally.
Figure 1 shows the SCC-AI signal connections.
Figure 1. SCC-AI Signal Connections
The inputs are designed in a floating (nonreferenced) single-ended
configuration. If the measured signals are floating, connect the negative
input pins, 1 and 3, to AI SENSE on the SC-2345/2350 terminal block or
AIGND on the SC-68, through a 10 kΩto 100 kΩresistor. Figure 2 shows
a floating signal connection on one channel of the SCC-AI.
+
–
+
4
–
+
–
3
2
1
E/M Series DAQ Device
Signal
Source
AI (X )
SCC-AI
AI SENSE
AI GND
AI (X+8)
+
–Lowpass
Filter
Lowpass
Filter
SCC-AI Series Isolated Analog Input Modules 6 ni.com
Figure 2. Nonreferenced Signal Connection for the SCC-AI (One Channel)
If a high common-mode voltage is present, connect the negative input pins,
1 and 3, to the signal reference. Figure 3 shows a ground-referenced signal
connection on one channel of the SCC-AI.
Figure 3. Ground-Referenced Signal Connection for the SCC-AI
with High Common-Mode Voltage (One Channel)
For information about how to configure the SCC-AI module using
NI-DAQmx, refer to the SCC Quick Start Guide.
+
4
–
+
–
3
2
1
E/M Series DAQ Device
Signal
Source
AI (X )
SCC-AI
AI SENSE
AI GND
AI (X+8)
+
–Lowpass
Filter
Lowpass
Filter
AI SENSE on
SC-2345/2350
terminal block
or
AI GND on
SCC-68
10 to 100 kΩ
+
4
–
+
–
3
2
1
E/M Series DAQ Device
AI (X )
SCC-AI
AI SENSE
AI GND
AI (X+8)
+
–Lowpass
Filter
Lowpass
Filter
+
–
Signal
Source
High
CMV
©National Instruments Corporation 7 SCC-AI Series Isolated Analog Input Modules
Using the SCC-AI when Scaling Voltage Measurements
If you configured the SCC-AI using Measurement & Automation Explorer
(MAX) and you are using NI-DAQmx, the voltage reading you get from the
E/M Series DAQ device accounts for the voltage scaling effect of the
SCC-AI. Otherwise, because the voltage measurement from the E/M Series
DAQ device is scaled by the gain given in Table 1, you must divide the
voltage reading returned by the E/M Series DAQ device by this gain to get
the correct input voltage.
Calibrating Gain and Offset Errors
The SCC-AI is calibrated at the factory before shipment. If you want to
adjust the gain of the SCC-AI in your system using your E/M Series DAQ
device, you need a voltage source that is several times more accurate than
the SCC itself and capable of providing the DC voltage shown in Table 2.
Gain Adjustment
To adjust the gain of the SCC-AI, complete the following steps:
1. Select the desired SCC-AI channel on the E/M Series DAQ device.
2. Set the gain on the E/M Series DAQ device so that its input range is
±10 V.
3. Connect the voltage source to the screw terminals of the desired
channel on the SCC-AI.
4. Apply the voltage given in Table 2 that corresponds to the SCC-AI
module. For example, if you have an SCC-AI03, you must apply
8 VDC.
Table 2. SCC-AI Input Voltage Requirements
Module Input Range
SCC-AI01 40 V
SCC-AI02 16 V
SCC-AI03 8 V
SCC-AI04 4 V
SCC-AI05 800 mV
SCC-AI06 80 mV
SCC-AI07 40 mV
SCC-AI13 8 V
SCC-AI14 4 V
SCC-AI Series Isolated Analog Input Modules 8 ni.com
5. Using your software, have the E/M Series DAQ device read the desired
channel on the SCC-AI and record the value.
6. Input 0 VDC to the SCC-AI.
7. Use the E/M Series DAQ device to read that channel and record the
value.
8. Subtract the values read (first reading – second reading).
9. Adjust the trimpot labeled Gain located on the top of the SCC-AI. If
the value you obtained in step 8 is less than the input voltage, turn the
trimpot clockwise to increase the gain. If it is greater than the input
voltage, turn the trimpot counterclockwise to decrease the gain.
10. Repeat steps 4 through 9 until the difference you get in step 8 equals
the Input Voltage Required value shown in Table 2; in this example the
value is 8 V using an SCC-AI03.
For example, assume that you have an SCC-AI03 module. You first connect
8 VDC to the input of CH (X). The E/M Series DAQ device reads 8.05 V
as the SCC output. You then connect 0 VDC to the input of CH (X) and the
E/M Series DAQ device reads –0.01 V as the SCC output. You subtract
these readings, 8.05 – (–0.01) =8.06, getting a difference of 8.06 V.
Because this difference is not equal to 8 V, you must adjust the gain trimpot
and repeat the procedure until the difference in outputs equals 8 V.
Note In this example there can be an offset voltage such that the final readings are 8.01 V
and 0.01 V for a difference of 8 V. The gain trimpot adjusted in step 9 of the previous
procedure adjusts only for gain errors and does not compensate for this offset voltage.
Offset Voltage Adjustment
Complete the following steps to adjust the offset voltage of the SCC-AI:
1. Select the desired SCC-AI channel on the E/M Series DAQ device.
2. Set the gain on the E/M Series DAQ device so that the input range
is ±10 V.
3. Connect the screw terminals of your desired channel on the SCC-AI
together.
4. Using your software, have the E/M Series DAQ device read the
channel.
5. If the value read is not equal to 0.00 V, adjust the appropriate trimpot
located on the top of the SCC-AI, labeled Offset. Turn the trimpot
clockwise to increase the offset.
6. Repeat steps 4 and 5 until the voltage read in step 4 equals 0.00 V.
©National Instruments Corporation 9 SCC-AI Series Isolated Analog Input Modules
Specifications
These ratings are typical at 25 °C unless otherwise stated.
Input Characteristics
Number of input channels ...................... 2 NRSE
Isolation.................................................. Bank isolation (isolation
per module)1
Input/output signal range, gain,
and bandwidth ........................................ Refer to Table 1
Input impedance
SCC-AI01, SCC-AI02 .................... 1 MΩ
All others......................................... 100 MΩ
Gain error ............................................... 4.5% max (trimmable to zero)
Gain stability .......................................... 150 PPM/°C
Offset error............................................. 40 mV max (RTI2)
Offset stability........................................ 225 µV/°C
Nonlinearity ........................................... 0.0128% typ
0.0260% max
Common-mode rejection ratio ............... 100 dB typical at 60 Hz
Output slew rate,
dependent on BW (filtering) .................. 0.8 V/µs max
Filter Characteristics
Number of poles..................................... 3
Rolloff .................................................... 60 dB/decade
Cutoff frequency (–3 dB)
AI0X................................................ 10 kHz
AI1X................................................ 4 Hz
1 The SCC-AI does not provide isolation between the two channels of the module. For more information,
refer to the Connecting the Input Signals section.
2 This specification is calculated relative to the input range of the module.
SCC-AI Series Isolated Analog Input Modules 10 ni.com
Power Requirement
Analog power .........................................410 mW max
+15 V ...............................................13.67 mA max
–15 V ...............................................13.67 mA max
Digital power (+5 V) ..............................650 mW max
130 mA max
Physical
Figure 4. SCC-AI Dimensions
Weight ....................................................37 g (1.0 oz)
I/O connectors.........................................One 20-pin right-angle
male connector,
one 4-pin screw terminal,
removable
Screw terminal wire gauge .....................24 to 12 AWG
Maximum Working Voltage
Maximum working voltage refers to the signal voltage plus the
common-mode voltage.
Channel-to-earth (inputs)........................42.4 Vpeak or 60 VDC,
Measurement Category I
Caution This device is rated for Measurement Category I and is intended to carry signal
voltages no greater than 42.4 Vpeak or 60 VDC. Do not use this device for connection to
signals or for measurements within Categories II, III, or IV.
1.87 cm
(0.74 in.) 7.93 cm
(3.12 in.)
3.55 cm
(1.4 in.)
©National Instruments Corporation 11 SCC-AI Series Isolated Analog Input Modules
Isolation Voltage
Channel-to-earth isolation
Continuous ...................................... 60 VDC,
Measurement Category I
Withstand ........................................ 2300 Vrms verified by a 5 s
dielectric withstand test
Channel-to-channel ................................ Nonisolated1
Environmental
Operating temperature............................ 0 to 50 °C
Storage temperature ............................... –20 to 70 °C
Humidity ................................................ 10 to 90% RH, noncondensing
Maximum altitude .................................. 2,000 m
Pollution Degree (indoor use only) ........ 2
Safety
The SCC-AI is designed to meet the requirements of the following
standards of safety for electrical equipment for measurement, control,
and laboratory use:
• IEC 61010-1, EN 61010-1
• UL 61010-1
• CAN/CSA-C22.2 No. 61010-1
Note For UL and other safety certifications, refer to the product label, or visit
ni.com/certification, search by model number or product line, and click the
appropriate link in the Certification column.
1 The SCC-AI does not provide isolation between the two channels of the module. For more information,
refer to the Connecting the Input Signals section.
SCC-AI Series Isolated Analog Input Modules 12 ni.com
Electromagnetic Compatibility
Emissions................................................EN 55011 Class A at 10 m
FCC Part 15A above 1 GHz
Immunity ................................................EN 61326:1997 + A2:2001,
Table 1
EMC/EMI ...............................................CE, C-Tick, and FCC Part 15
(Class A) Compliant
Note For EMC compliance, operate this device with shielded cabling.
CE Compliance
The SCC-AI meets the essential requirements of applicable European
Directives, as amended for CE marking, as follows:
Low-Voltage Directive (safety)..............73/23/EEC
Electromagnetic Compatibility
Directive (EMC) .....................................89/336/EEC
Note Refer to the Declaration of Conformity (DoC) for this product for any additional
regulatory compliance information. To obtain the DoC for this product, visit
ni.com/certification, search by model number or product line, and click the
appropriate link in the Certification column.
©National Instruments Corporation 13 SCC-AI Series Isolated Analog Input Modules
SCC-AI Module Pin Assignments
Figure 5 shows the I/O connector pins on the bottom of the module.
Figure 5. SCC Module Bottom View
Table 3 lists the signal corresponding to each I/O connector pin on the
bottom of the SCC-AI. AI (X) and AI (X+8) are the analog input channels
of the E/M Series DAQ device. AI GND is the analog input ground signal
and is the reference for AI (X) and AI (X+8). A GND is the reference for
the ±15 V supplies and REF 5 V. AI GND and A GND connect to the
SC-2345/2350 at the SCC-PWR connector. GND is the reference for the
+5Vsupply.
1Pin1 2Pin2 3 Pin19 4Pin20
1
2
3
4
National Instruments, NI, ni.com, and LabVIEW are trademarks of National Instruments Corporation.
Refer to the Terms of Use section on ni.com/legal for more information about National
Instruments trademarks. Other product and company names mentioned herein are trademarks or trade
names of their respective companies. For patents covering National Instruments products, refer to the
appropriate location: Help»Patents in your software, the patents.txt file on your CD, or
ni.com/patents.
© 2002–2005 National Instruments Corporation. All rights reserved. 371066C-01 Dec05
Table 3. SCC-AI Module Pin Assignments
Pin Number Signal
1E/M Series AI (X)
2E/M Series AI GND
3 —
4E/M Series AI (X+8)
5 —
6E/M Series AI GND
7 —
8E/M Series AI GND
9+5 V
10 GND
11 A GND
12 REF 5 V
13 +15 V
14 –15 V
15 —
16 —
17 —
18 —
19 —
20 —
This manual suits for next models
9
Table of contents
Other NI I/O System manuals
