Ni Measurement Studio User Manual

Measurement Studio

TM

User Manual

Subtitle

Measurement Studio User Manual

April 2008

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7

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LIMITATION, THE APPROPRIATE DESIGN, PROCESS AND SAFETY LEVEL OF SUCH SYSTEM OR APPLICATION.

Contents

About This Manual

How To Use This Manual..............................................................................................ix

Conventions ...................................................................................................................x

Chapter 1

Introduction to Measurement Studio

Installation Requirements ..............................................................................................1-2

Driver Support .................................................................................................1-3

Deployment Requirements ............................................................................................1-3

Installation Instructions..................................................................................................1-3

Installing Hardware Drivers for Visual Studio 2008 Support .........................1-4

Installing Hardware Drivers for Visual Studio 2005 Support .........................1-5

Installing the Current Version of Measurement Studio over

Previous Versions of Measurement Studio ..................................................1-6

Measurement Studio Package Comparison Chart .........................................................1-6

Learning Measurement Studio.......................................................................................1-9

Chapter 2

Measurement Studio .NET Class Libraries

Measurement Studio Support for Visual Studio .NET Class Library Overview...........2-1

Analysis .........................................................................................................................2-2

Standard Analysis............................................................................................2-2

Professional Analysis ......................................................................................2-2

Enterprise Analysis..........................................................................................2-3

Common.........................................................................................................................2-13

Data Transfer .................................................................................................................2-14

Network Variable ............................................................................................2-14

DataSocket.......................................................................................................2-15

NI-488.2 .........................................................................................................................2-16

NI-DAQmx ....................................................................................................................2-16

NI-SCOPE .....................................................................................................................2-17

NI-VISA.........................................................................................................................2-17

User Interface.................................................................................................................2-18

Windows Forms Controls ..............................................................................................2-19

Waveform Graph and Scatter Graph Controls ................................................2-20

Digital Waveform Graph Control....................................................................2-23

Complex Graph Control ..................................................................................2-25

Legend Control................................................................................................2-27

© National Instruments Corporation v

Measurement Studio User Manual

Contents

Numeric Controls ............................................................................................ 2-27

Numeric Edit Control...................................................................................... 2-29

Switch and LED Controls ............................................................................... 2-30

Property Editor Control................................................................................... 2-32

Windows Forms Array Controls ................................................................................... 2-33

Switch and LED Array Controls ..................................................................... 2-33

Numeric Edit Array Control ........................................................................... 2-34

InstrumentControlStrip Control ...................................................................... 2-35

ASP.NET Web Forms Controls .................................................................................... 2-37

Waveform Graph and Scatter Graph Controls ................................................ 2-38

Digital Waveform Graph Control ................................................................... 2-40

Complex Graph Control.................................................................................. 2-42

Legend Control ............................................................................................... 2-44

Numeric Controls ............................................................................................ 2-44

Numeric Edit Control...................................................................................... 2-47

Switch and LED Controls ............................................................................... 2-48

AutoRefresh Control ....................................................................................... 2-49

AutoRefresh Callback ..................................................................................... 2-49

Chapter 3

Measurement Studio Visual C++ Class Libraries

Measurement Studio Visual C++ Class Library Overview........................................... 3-1

ActiveX Controls in Visual C++ ................................................................................... 3-2

3D Graph Control .......................................................................................................... 3-2

Plot Operations................................................................................................ 3-3

Additional Operations ..................................................................................... 3-3

Analysis ......................................................................................................................... 3-3

Standard Analysis ........................................................................................... 3-4

Professional Analysis ...................................................................................... 3-4

Enterprise Analysis ......................................................................................... 3-4

Common ........................................................................................................................ 3-15

DataSocket..................................................................................................................... 3-15

Microsoft Excel Interface .............................................................................................. 3-16

Microsoft Word Interface .............................................................................................. 3-16

NI-488.2......................................................................................................................... 3-17

NI-DAQmx.................................................................................................................... 3-17

NI-Reports ..................................................................................................................... 3-18

NI-VISA ........................................................................................................................ 3-18

User Interface ................................................................................................................ 3-19

Button Control................................................................................................. 3-19

Graph Control ................................................................................................. 3-20

Plot Operations ................................................................................. 3-20

Axis Operations ................................................................................ 3-21


vi ni.com

Contents

Additional Operations .......................................................................3-21

Knob Control ...................................................................................................3-21

Numeric Edit Control ......................................................................................3-22

Slide Control....................................................................................................3-23

Utility .............................................................................................................................3-24

Chapter 4

Measurement Studio Integrated Tools and Features

Measurement Studio Menu ............................................................................................4-1

Creating a Measurement Studio Project ........................................................................4-4

Adding or Removing Measurement Studio .NET Class Libraries ................................4-5

Creating a Measurement Studio NI-DAQmx Application ............................................4-6

Creating an NI-DAQmx User Interface ..........................................................4-8

Creating NI-DAQmx User Code in Visual C++ .............................................4-9

Creating an Instrument Control Application .................................................................4-9

Selecting a Measurement Studio Parameter Value........................................................4-11

Using the Instrument Driver Wizard .............................................................................4-12

Chapter 5

Getting Started with Measurement Studio

Measurement Studio Walkthroughs...............................................................................5-1

Walkthrough: Creating a Measurement Studio Application with Windows Forms Controls and Analysis ............................................................5-2

Walkthrough: Creating a Measurement Studio Application with Web Forms Controls and Analysis ....................................................................5-11

Walkthrough: Creating a Measurement Studio Application with Windows Forms Controls and Network Variable ..............................................5-22

Walkthrough: Creating a Measurement Studio Application with Web Forms Controls and Network Variable ......................................................5-31

Walkthrough: Creating a Measurement Studio NI-DAQmx Application .....................5-42

Walkthrough: Creating a Measurement Studio Instrument I/O Application ................5-52

Appendix A

Technical Support and Professional Services

Glossary

Index

© National Instruments Corporation vii


About This Manual

The Measurement Studio User Manual introduces the concepts associated with the Measurement Studio class libraries and development tools. This manual assumes that you have a general working knowledge of Microsoft

Visual Studio and the .NET Framework for .NET application development or MFC for unmanaged C++ application development.

How To Use This Manual

Measurement Studio 8.5 includes two Visual Studio support CDs—one with support for Visual Studio .NET 2003, Visual Studio 2005, and Visual

Studio 2008 and one with support for Visual Studio 6.0. This manual documents Measurement Studio for Visual Studio 2005/2008. The

Measurement Studio support for Visual Studio .NET 2003, Visual

Studio 2005, and Visual Studio 2008 CD includes separate, parallel sets of class libraries, integration features, and support documentation for developing with Visual Studio .NET 2003, Visual Studio 2005, and Visual

Studio 2008. For help with Visual Studio 6.0, refer to the Measurement

Studio Support for Visual Studio 6.0 Readme located on the Measurement

Studio for Visual Studio 6.0 CD.

The Measurement Studio User Manual is organized into five chapters.

Chapter 1, Introduction to Measurement Studio , is an overview of

Measurement Studio. This chapter includes installation and deployment requirements, installation instructions, and a list of Measurement Studio

resources. Chapter 2, Measurement Studio .NET Class Libraries , and

Chapter 3, Measurement Studio Visual C++ Class Libraries , include

information about the .NET class libraries and the Visual C++ class

libraries, respectively. Chapter 4, Measurement Studio Integrated Tools and Features , includes information on using the Measurement Studio tools

and features integrated into the Visual Studio environment. Chapter 5,

Getting Started with Measurement Studio

, includes walkthroughs that guide you through step-by-step instructions on how to develop with

Measurement Studio features.

Note Refer to the Measurement Studio Release Notes for updates or changes to the

Measurement Studio User Manual .

© National Instruments Corporation ix


About This Manual

Use this manual as a starting point to learn about Measurement Studio.

Refer to the NI Measurement Studio Help within the Visual Studio environment for function reference and detailed information about the

Measurement Studio class libraries, wizards, assistants, and other features.

<>

»

Conventions

bold italic monospace

The following conventions appear in this manual:

Text enclosed in angle brackets represents directory names and parts of paths that may vary on different computers, such as < Windows\System >.

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 tip, which alerts you to advisory information.

This icon denotes a note, which alerts you to important information.

Bold text denotes items that you must select or click on in the software, such as menu items and dialog box options. Bold text also denotes class library member names or emphasis.

Italic text denotes parameters, variables, cross-references, 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.

Text in this font denotes text or characters that you enter from the keyboard, sections of code, programming examples, and syntax examples. This font also is used for the proper names of disk drives, paths, directories, programs, device names, filenames and extensions, and code excerpts.


x ni.com

1

Introduction to Measurement

Studio

Measurement Studio is an integrated suite of tools and class libraries that are designed for developers using Microsoft Visual Basic .NET, Visual C#,

ASP.NET, and Visual C++ to develop measurement and automation applications.

Measurement Studio dramatically reduces application development time through object-oriented measurement hardware interfaces, advanced analysis libraries, scientific user interface controls for Windows and Web applications, measurement data networking, wizards, interactive code designers, and highly extensible .NET and Visual C++ classes. You can use

Measurement Studio to develop a complete measurement and automation application that includes data acquisition, analysis, and presentation functionalities.

Measurement Studio 8.5 Professional and Enterprise packages include two Visual Studio support CDs—one CD with support for Visual Studio

.NET 2003, Visual Studio 2005, and Visual Studio 2008 and one CD with support for Visual Studio 6.0. The Measurement Studio 8.5 Standard package includes one CD with support for Visual Studio .NET 2003, Visual

Studio 2005, and Visual Studio 2008. Visual Studio 6.0 support includes

ActiveX controls for use in Visual Basic 6.0 and MFC class libraries and

ActiveX controls for use in Visual C++ 6.0. Visual Studio .NET 2003 support and Visual Studio 2005 support includes .NET class libraries and controls for use with .NET languages and MFC class libraries and ActiveX controls for use with Visual C++. Visual Studio 2008 support includes only .NET class libraries and controls for use with .NET languages.

Measurement Studio 8.5 does not include MFC class libraries or ActiveX controls for use in Visual C++ in Visual Studio 2008.

Note Measurement Studio 8.5 support for Visual Studio .NET 2003 includes updates to the ActiveX controls; however, no new features for Visual Studio .NET 2003 are included in Measurement Studio 8.5.

© National Instruments Corporation 1-1


Chapter 1 Introduction to Measurement Studio

This manual documents Measurement Studio for Visual Studio 2005 and

Visual Studio 2008. For help with Visual Studio 6.0 support, refer to the

Measurement Studio Support for Visual Studio 6.0 Readme located on the

Measurement Studio for Visual Studio 6.0 CD. For help with Visual Studio

.NET 2003 support, refer to the Measurement Studio Support for Visual

Studio .NET 2003 Readme located on the CD for Measurement Studio for

Visual Studio .NET 2003. After installing Visual Studio .NET 2003 support, you can refer to the Measurement Studio User Manual by selecting

Start»All Programs»National Instruments»<Measurement Studio for

.NET 2003>»User Manual .

Note Refer to the Measurement Studio Release Notes for updates or changes to the

Measurement Studio User Manual.

Installation Requirements

To use Measurement Studio, your computer must have the following:

• Microsoft Windows Vista/XP/2000 for Visual Studio 2005 or

Microsoft Windows Vista/XP for Visual Studio 2008

Note If you have Windows Vista installed you must also have both Visual Studio 2005

Service Pack 1 and Visual Studio Service Pack 1 Update for Windows Vista installed on your machine for Measurement Studio to function properly.

• Microsoft .NET Framework 2.0 for Visual Studio 2005 or Microsoft

.NET Framework 3.5 for Visual Studio 2008 (required only for the

Measurement Studio .NET class libraries)

• Standard, Professional, or Team System edition of Microsoft Visual

Studio 2005 or Standard, Professional, or Team System edition of

Microsoft Visual Studio 2008 (required to use the Measurement Studio integrated tools) or Visual C#, Visual Basic .NET, or Visual C++

Express editions of Microsoft Visual Studio 2005 or Microsoft Visual

Studio 2008

• Intel Pentium III class processor, 1 GHz or higher

• Video display—1024

×

768, 256 colors (16-bit color recommended for user interface controls)

• Minimum of 256 MB of RAM (512 MB or higher recommended)

• Minimum of 385 MB of free hard disk space for Visual Studio 2005 support or minimum of 200 MB of free hard disk space for Visual

Studio 2008 support


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• Microsoft-compatible mouse

• Microsoft Internet Explorer 6.0 or later

Optional Installation —In order for links from Measurement Studio help topics to .NET Framework help topics to work, you must install the

Microsoft .NET Framework SDK 2.0 or Microsoft .NET Framework

SDK 3.5.

Driver Support

To use .NET class libraries that interface to National Instruments device drivers, NI-DAQmx, NI-VISA and NI-488.2, and the MAX (Measurement

& Automation Explorer) configuration utility, you must install the underlying device drivers in addition to the .NET class libraries. You can run the underlying device driver installers from the NI Device Drivers CD included with Measurement Studio. Alternatively, refer to NI Drivers and

Updates on ni.com

and enter Device Drivers into the search field to download the latest version of the NI Device Drivers CD.

Deployment Requirements

To deploy an application built with Measurement Studio .NET class libraries, the target computer must have a Windows Vista/XP/2000 operating system and the .NET Framework version 2.0 for Visual Studio

2005 or the .NET Framework version 3.5 for Visual Studio 2008.

To deploy an application built with Measurement Studio Visual C++ class libraries, the target computer must have a Windows Vista/XP/2000 operating system.

Installation Instructions

Complete the following steps to install Measurement Studio. These steps describe a typical installation. Please carefully review all additional licensing and warning dialog boxes.

National Instruments recommends that you exit all programs before running the Measurement Studio installer. Applications that run in the background, such as virus scanning utilities, might cause the installer to take longer than average to complete.




Note There are separate installers for Measurement Studio support for Visual Studio 2005 and Measurement Studio support for Visual Studio 2008. Repeat the installation instructions to install support for both. When installing support for more than one version of Visual Studio, you can reduce installation time by running the Device Drivers CD installer only once. To do this, ensure that the Device Drivers CD feature is enabled only for the last Measurement Studio Visual Studio support installer that you run.

The option to browse for an installation location is valid only if you have not already installed any Measurement Studio features for the version of

Visual Studio or the .NET Framework that you are installing. If you have any Measurement Studio features installed, then Measurement Studio installs to the same root directory to which you installed other

Measurement Studio features.

Complete the following steps to install Measurement Studio:

1.

Log on as an administrator or as a user with administrator privileges.

2.

Launch Autorun.exe

, either from the installation CD or from the location to which you extracted the downloaded CD image.

3.

Select the version of Visual Studio you want to install support for.

4.

Follow the instructions that appear on the screen.

Note If you want to upgrade a Windows XP machine to Windows Vista, National

Instruments recommends first uninstalling all NI software, including both application software and drivers.

Installing Hardware Drivers for Visual Studio 2008 Support

Visual Studio 2008 .NET class library support for National Instruments hardware drivers is included on the Measurement Studio 8.5 CD, under the

VS2008 Driver Support feature in the feature tree. To install support for

NI-DAQmx, NI-VISA, NI-488.2, or MAX, you must install the appropriate feature from the Measurement Studio 8.5 CD and you must install the underlying device driver from the NI Device Drivers CD or from a product-specific driver installer. Refer to the Driver Support section for information on obtaining device driver installers.


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To install support for NI-DAQmx:

1.

In the NI Measurement Studio 8.5 installer, enable the VS2008 Driver

Support».NET Framework 3.5 Languages Support for

NI-DAQmx feature.

2.

In the NI Device Drivers installer, enable the Data Acquisition»

NI-DAQmx feature.

To install support for NI-VISA:

1.


Support».NET Framework 3.5 Languages Support for NI-VISA feature. If you want to use the Instrument I/O Assistant inside Visual

Studio 2008, enable the VS2008 Driver Support»VS2008 DotNET

IIOAssistant Support feature.

2.

In the NI Device Drivers installer, enable the Instrument Control»

NI-VISA feature.

To install support for NI-488.2:

1.


Support».NET Framework 3.5 Languages Support for NI-488.2 feature.

2.

In the NI Device Drivers installer, enable the Instrument Control»

NI-488.2 feature.

To install support for MAX:

1.


Support».NET Framework 3.5 Languages Support for NI MAX feature.

2.

In the NI Device Drivers installer, enable the NI Measurement and

Automation Explorer feature.

Installing Hardware Drivers for Visual Studio 2005 Support

The .NET and C++ class libraries for Visual Studio 2005 support for

National Instruments hardware drivers are included in the Driver CD installer.




Installing the Current Version of Measurement Studio over Previous

Versions of Measurement Studio

Note You can have only one version of Measurement Studio installed on a system for each version of Visual Studio or the .NET Framework installed on the system. For example, you can have Measurement Studio 8.1.2 for Visual Studio 2005 installed on the same system as Measurement Studio 8.5 for Visual Studio 2008, but you cannot have

Measurement Studio 8.1.2 for Visual Studio 2005 installed on the same system as

Measurement Studio 8.5 for Visual Studio 2005.

If you install a newer version of Measurement Studio on a machine that has a prior version of Measurement Studio installed, the newer version installer replaces the prior version functionality, including class libraries. However, the prior version assemblies remain in the global assembly cache (GAC); therefore, applications that reference the prior version continue to use the prior version .NET assemblies.

Note This does not apply to NationalInstruments.Common.dll

.

NationalInstruments.Common.dll

uses a publisher policy file to redirect applications to always use the newest version of NationalInstruments.Common.dll

installed on the system, for each version of the .NET Framework.

NationalInstruments.Common.dll

is backward-compatible.

Measurement Studio Package Comparison Chart

The following table lists the features included in the Standard,

Professional, and Enterprise packages of Measurement Studio. Refer to ni.com/mstudio for more information about the functionality and features included with each Measurement Studio package, including Visual

C++ functionality.


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Table 1-1. Measurement Studio Package Comparison Chart for Visual C# and Visual Basic .NET

Feature

Project Wizards

Windows Forms User

Interface Controls

Standard Analysis

Libraries 1

NI-488.2 Class

Libraries 2

NI-VISA Class

Libraries 2

NI-DAQmx Class

Libraries 2

.NET Instrument

Driver Wizard

User Interface

DataSocket Binding

Web Forms User

Interface Controls

MFC and ActiveX

Controls for

Visual C++ 6.0

Professional Analysis

Libraries 3

3D Graph ActiveX

Control

User Interface

Network Variable

Binding

Network Variable

Class Library

Network Variable

Data Source

Standard Edition

✔

✔

✔

✔

✔

✔

✔

✔

Professional Edition

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

Enterprise Edition

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔




Table 1-1. Measurement Studio Package Comparison Chart for Visual C# and Visual Basic .NET (Continued)

Feature

DataSocket Server

DataSocket Library

Parameter Assistant

Standard Edition Professional Edition

✔

✔

✔

✔

Enterprise Edition

✔

✔

✔

✔

Instrument I/O

Assistant 2

DAQ Assistant 2

Enterprise Analysis

Libraries 4

✔ ✔

✔

NI TestStand

Integration

LabWindows ™ /CVI ™

Full Development

System (FDS)

✔

✔

1 Refer to the

Standard Analysis

section of Chapter 2, Measurement Studio .NET Class Libraries , for a list of the

functionality included in the Standard Analysis class library.

2 Included with the Device Drivers CD.

3 Refer to the Professional Analysis section of Chapter 2, Measurement Studio .NET Class Libraries , for a list of the functionality included in the Professional Analysis class library.

4 Refer to the Enterprise Analysis section of Chapter 2, Measurement Studio .NET Class Libraries , for a list of the functionality included in the Enterprise Analysis class library.


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Learning Measurement Studio

As you work with Measurement Studio, you might need to consult additional resources. For detailed Measurement Studio help, including function reference and in-depth documentation on developing with

Measurement Studio, refer to the NI Measurement Studio Help within the

Visual Studio environment. The NI Measurement Studio Help is fully integrated with the Visual Studio help. You must have Visual Studio installed to view the online help, and you must have the Microsoft .NET

Framework SDK 2.0 for Visual Studio 2005 or the Microsoft .NET

Framework SDK 3.5 for Visual Studio 2008 installed in order for links from Measurement Studio help topics to .NET Framework help topics to work. You can launch the NI Measurement Studio Help in the following ways:

• From the Windows Start menu, select Start»All Programs»National

Instruments»<Measurement Studio>»Measurement Studio

Documentation . The help launches in a stand-alone help viewer.

• From Visual Studio, select Help»Contents to view the Visual Studio table of contents. The NI Measurement Studio Help is listed in the table of contents.

• From Visual Studio, select Measurement Studio»NI Measurement

Studio Help . The help launches within the application.

Tip As you work through this manual, you will see italicized references to relevant help topics. To find these topics, use the table of contents in the NI Measurement Studio Help installed on your machine.

The following resources also are available to provide you with information about Measurement Studio.

• Getting Started information—Refer to the Measurement Studio Core

Overview topic and the Getting Started with the Measurement Studio

Class Libraries section in the NI Measurement Studio Help for an introduction to Measurement Studio and for walkthroughs that guide you step-by-step in learning how to develop Measurement Studio applications. For an introduction to Measurement Studio resources, refer to the Using the Measurement Studio Help topic in the

NI Measurement Studio Help .

• Examples—Measurement Studio installs examples organized by class library, depending on the component, the version of Visual Studio or the .NET Framework that the example supports, the version of

Measurement Studio installed on the system, and the operating system.




For more information on example locations, refer to Where To Find

Examples .

•

NI Technical Support—Refer to Appendix A, Technical Support and

Professional Services

, for more information.

• Measurement Studio Web site, ni.com/mstudio —Contains

Measurement Studio news, support, downloads, white papers, product tutorials, and evaluation software.

• NI Developer Zone, zone.ni.com

—Provides access to online example programs, tutorials, technical news, and a Measurement

Studio Discussion Forum where you can participate in discussion forums for Visual Basic 6.0, Visual C++, and .NET Languages.

• Measurement Studio .NET Class Hierarchy Chart and Measurement

Studio Visual C++ Class Hierarchy Chart —Provide overviews of class relationships within class libraries. Charts are included with all

Measurement Studio packages and are posted online at ni.com/ manuals .

• Review the information from the Microsoft Web site on using Visual

Studio.


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2

Measurement Studio .NET Class

Libraries

This chapter provides overview information about the .NET class libraries included with Measurement Studio support for Visual Studio 2005 and

Visual Studio 2008. Refer to the Using the Measurement Studio .NET Class

Libraries section of the NI Measurement Studio Help for detailed

information about these libraries. Refer to Chapter 5, Getting Started with

Measurement Studio , for step-by-step instructions on developing

applications with these libraries.

Measurement Studio Support for Visual Studio .NET

Class Library Overview

Measurement Studio provides .NET class libraries that you can use to develop complete measurement and automation applications in Visual

Basic .NET and Visual C#.

Measurement Studio includes the following .NET class libraries:

• Analysis

• Common

• DataSocket

• Network Variable

• NI-488.2

• NI-DAQmx

• NI-SCOPE

• NI-VISA

• User Interface

Refer to the following sections for information about each Measurement

Studio .NET class library.



Chapter 2 Measurement Studio .NET Class Libraries

Analysis

The Measurement Studio Analysis .NET class library is in the

NationalInstruments.Analysis

namespace. The Analysis class library includes a set of classes that provides digital signal processing, signal filtering, signal generation, peak detection, and other general mathematical functionality. Use this library to analyze acquired data or to generate data. Additionally, the documentation for the Analysis class library includes analysis code snippets that you can copy and paste into an application and use immediately.

The functionality included in the Analysis library varies based on the

Measurement Studio package you purchase. Refer to the following sections for information about the Standard, Professional, and Enterprise Analysis class libraries.

Standard Analysis

The Standard Analysis class library, which ships with Measurement Studio

Standard Edition, includes the sawtooth, sine, square, triangle, and basic function wave generators.

Professional Analysis

The Professional Analysis class library, which ships with Measurement

Studio Professional Edition, includes the Standard Analysis functionality as well as the following functionality:

• Bessel, Chebyshev, Inverse Chebyshev, Windowed, Kaiser, and

Elliptic Low, High, Bandpass, and Bandstop filters

• Signal processing functions such as convolution, deconvolution, correlation, decimation, integration, and differentiation

• FFT, Inverse FFT, Real FFT, Fast Hartley, Inverse Fast Hartley, Fast

Hilbert, Inverse Fast Hilbert, DST, Inverse DST, DCT, and Inverse

DCT transformations

• Linear algebra functions such as determinant, check positive definiteness, calculate dot product, and other various matrix functions

• Scaled and unscaled windowing classes

• Common statistical functions such as mean, median, mode, and variance

• Exponential, linear, and polynomial curve fitting functions

• Signal generation functions


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Enterprise Analysis

The Enterprise Analysis class library, which ships with Measurement

Studio Enterprise Edition, includes the Standard and Professional Analysis functionality as well as the following advanced functionality:

• EquiRipple filters

• Linear algebra functions such as forward and back substitution,

LU factorization, Cholesky factorization, Schur decomposition, and Hessenberg decomposition

• Probability and analysis of variance

• Sinc, impulse, pulse, ramp, and chirp patterns

• General least square curve fit, power fit, log fit, Gauss fit, cubic spline fit, and interpolation functions

• Measurement functions such as transition measurements, pulse measurements, and cycle RMS average functions

• Special functions

Refer to Table 2-1 to determine the type of measurements available in the

Professional and Enterprise Analysis .NET libraries.

Table 2-1. Analysis .NET Library Measurement Types included in the Professional and Enterprise Packages

Analysis .NET Library Professional Package

Measurements

Enterprise Package

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AC and DC Estimator

Amplitude and Phase

Spectrum

Auto Power Spectrum

Cross Power Spectrum

Cycle RMS Average

Harmonic Analyzer

Harmonic Analyzer Using

Signal

Impulse Response Function

Network Functions (avg)

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Table 2-1. Analysis .NET Library Measurement Types included in the Professional and Enterprise Packages (Continued)

Professional Package Analysis .NET Library

Power and Frequency Estimate

Pulse Measurements

Scaled Time Domain Window

Single Tone Information

Spectrum Unit Conversion

State Levels

Transfer Function

Transition Measurements


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Signal Generation

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Arbitrary Wave

Chirp Pattern

Gaussian White Noise

Impulse Pattern

Pulse Pattern

Ramp Pattern

Sawtooth Wave

Sinc Pattern

Sine Pattern

Sine Wave

Square Wave

Triangle Wave

Uniform White Noise

Blackman Window

Blackman-Harris Window

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Windowing

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Analysis .NET Library

Blackman-Nuttall Window

Cosine Tapered Window

Dolph-Chebyshev Window

Exact Blackman Window

Exponential Window

Flat Top Window

Force Window

Gauss Window

General Cosine Window

Hamming Window

Hanning Window

Kaiser-Bessel Window

Scaled Time Domain Windows

Symmetric Time Domain

Windows

Triangle Window


Professional Package

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Bessel

Butterworth

Cascade

Chebyshev

Elliptic

Equiripple

FIR

FIR Windowed

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Filters

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IIR Cascade

IIR

Inverse Chebyshev

Kaiser

Autocorrelation

Convolution

Cross Power

Cross Correlation

Decimate

Deconvolution

Derivative x(t)

Discrete Cosine Transform

Discrete Sine Transform

Fast Hilbert Transform

Fast Hartley Transform

Integral x(t)


Inverse Real and Complex Fast

Fourier Transform (FFT)

Inverse Fast Hilbert Transform

Inverse Fast Hartley Transform

Peak Detection

Power Spectrum

Pulse Parameters

Real and Complex FFT


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Signal Processing

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Threshold Peak Detector

Unwrap Phase



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Linear Algebra


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Back Transform Eigen Vectors

Backward Substitution

Cholesky Factorization

Complex Back Transform

Eigen Vectors

Complex Cholesky

Factorization

Complex Determinant

Complex Dot Product

Complex Eigen Vectors and

Eigen Values

Complex General Eigen AB

Complex Hessenberg

Decomposition

Complex Inverse Matrix

Complex Linear Equations

Complex LU Factorization

Complex Matrix Balance

Complex Matrix Condition

Number

Complex Matrix Norm

Complex Matrix Rank

Complex Outer Product

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Complex Pseudo Inverse

Matrix

Complex QR Factorization

Complex QR Factorization with Pivot Matrix

Complex QR Factorization with Pivot Vector

Complex QZ Decomposition

Complex Schur

Decomposition

Complex Solve Linear

Equations (Multiple Right

Hand)


Equations (Single Right Hand)

Complex SVD Factorization

Complex Vector Norm

Determinant

Dot Product

Forward Substitution

General Eigen AB

Hessenberg Decomposition

Inverse Matrix

Linear Equations

LU Factorization

Matrix Balance

Matrix Condition Number

Matrix Multiplication


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Matrix Norm

Matrix Rank

Outer Product

Pseudo Inverse Matrix

QR Factorization

QR Factorization with Pivot

Matrix


Vector

QZ Decomposition

Schur Decomposition

Solve Linear Equations

(Multiple Right Hand)


(Single Right Hand)

Special Matrix

SVD Factorization

Test Positive Definite Matrix

Trace

Transpose


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1D and 2D Array Arithmetic

1D and 2D Linear Evaluation

1D and 2D Polynomial

Evaluation

1D Polar to Rectangular

1D Rectangular to Polar

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Array and Numeric Operations

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Complex Number Arithmetic

Find Polynomial Roots

Scale 1D and 2D



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Curve Fitting


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Cubic Spline Fit

Exponential Fit

Exponential Fit Interval

Gauss Fit

Gauss Fit Interval

General Least Squares

Linear Fit

General Polynomial Fit

Goodness of Fit

Linear Fit

Linear Fit Interval

Logarithm Fit

Logarithm Fit Interval

Nonlinear Fit

Power Fit

Power Fit Interval

Remove Outliers

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Statistics

1D, 2D, and 3D ANOVA

Chi-Square Distribution erf(x) and erfc(x)

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F-Distribution

Histogram

Inverse Chi-Square

Distribution

Inverse F-Distribution

Inverse Normal Distribution

Inverse T-Distribution

Mean

Median and Mode

Moment about Mean

Normal Distribution

Polynomial Interpolation

Root-Mean-Square (RMS)

Spline Interpolant

Spline Interpolation

Standard Deviation

T-Distribution

Variance

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Special Functions

Airy

Bessel 1st

Bessel 2nd

Beta

Complimentary Gamma

Cosine Integral

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Dawson’s Integral

Dilogarithm

Elliptic 1st

Elliptic 2nd

Exponential Integral

Factorial

Fresnel Integrals

Gamma

Gauss Hypergeometric

Hyperbolic Cosine Integral

Hyperbolic Sine Integral

Incomplete Beta

Incomplete Elliptic 1st

Incomplete Elliptic 2nd

Incomplete Gamma

Jacobian Elliptic Function

Kelvin 1st

Kelvin 2nd

Kummer

Logarithm of Factorial

Modified Bessel 1st

Modified Bessel 2nd

Parabolic Cylinder

Psi

Sine Integral


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Spherical Bessel 1st

Spherical Bessel 2nd

Stirling

Struve

Tricomi

Zeta


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Tip For more information about analyzing or generating data with the Analysis class library, refer to the Using the Measurement Studio Analysis .NET Library topic in the

NI Measurement Studio Help . For more information about the functionality included in the

Analysis class library, visit ni.com/analysis and select Visual Basic, Visual Basic

.NET, C++, and C# with Measurement Studio .

Common

The Measurement Studio Common .NET class library is in the

NationalInstruments namespace. The Common class library provides a set of classes that facilitates the exchange of data between the acquisition, analysis, and user interface portions of your application. The Common class library includes the following features:

• A ComplexDouble data type. This data type represents a complex number of type Double that is composed of a real part and an imaginary part.

• A DigitalWaveform data type. This data type represents a set of digital states that are grouped by samples or signals.

• A ComplexWaveform data type. This data type represents an analog signal that varies over time and is composed of complex data values.

• An AnalogWaveform data type. This data type represents an analog signal that varies over time.

• A DataConverter class that converts data from one data type to another data type, such as converting an array of integers to an array of doubles.




• An EngineeringFormatInfo class that defines a custom formatter to format numeric values as strings with engineering notation and

International System of Units (SI) prefixes and symbols.

• A PrecisionWaveformTiming class that you can use to represent the timing of an analog or digital waveform that is accurate to the nearest 2-64 second.

• An AnalogWaveformCollection class that contains a strongly typed collection of AnalogWaveform<TData> objects; one object for each channel and record combination. You can access these objects through the 1D indexer or the 2D indexer.

Tip For more detailed information about the Common class library, refer to the

National Instruments section in the NI Measurement Studio Help .

Data Transfer

You can use the NetworkVariable class library or the DataSocket class library to transfer live measurement data between applications over a network. You can use NetworkVariable or DataSocket to exchange different types of data between Measurement Studio, LabVIEW,

LabWindows/CVI, and other applications that support NI-Publish

Subscribe Protocol ( psp: ). NetworkVariable is the preferred method for transferring data between these applications, and, in these cases,

NetworkVariable supersedes DataSocket. You can also use

NetworkVariable and DataSocket to exchange different types of data between OLE for Process Control ( opc: ) servers. Exchanging data between Measurement Studio applications and OPC servers with

NetworkVariable requires LabVIEW DSC Run-Time System. Use

DataSocket to communicate directly with an OPC server.

Network Variable

The Measurement Studio Network Variable .NET class library includes three namespaces: NationalInstruments.NetworkVariable

,

NationalInstruments.NetworkVariable.WindowsForms

, and

NationalInstruments.NetworkVariable.WebForms

. You use the

Network Variable class library to transfer live measurement data between applications and servers over the network. You use WindowsForms and

WebForms data sources to expose Network Variable data items that you can bind to properties of a Windows Forms or a Web Forms control.


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Use the features in the Network Variable class library to perform the following operations:

• Exchange different types of data between Measurement Studio,

LabVIEW, LabWindows/CVI, and other applications that support

NI-Publish Subscribe Protocol ( psp: ) and OLE for Process Control

( opc: ) servers. Exchanging data between Measurement Studio applications and OPC servers requires LabVIEW DSC.

Note Measurement Studio and LabWindows/CVI refer to variables as network variables and LabVIEW refers to variables as shared variables. However, you can read to and write from Measurement Studio and LabWindows/CVI network variables with LabVIEW shared variables.

• Use Windows Forms and Web Forms data sources to expose Network

Variable data items that you can bind to properties of a Windows

Forms or a Web Forms control.

• Use the NationalInstruments.NetworkVariable.Browser

classes to discover network variables and processes.

• Use the NationalInstruments.NetworkVariable.

ServerProcess , NationalInstruments.NetworkVariable.

ServerProcessInfo , NationalInstruments.

NetworkVariable.ServerVariable

, and

NationalInstruments.NetworkVariable.

ServerVariableInfo classes to explicitly create network variables.

• Use the Network Variable Browser dialog box to quickly locate and select data items on other computers and servers. The Browser Dialog is included in the WindowsForms class.

Tip For more detailed information about the Network Variable class library, refer to the

Using the Measurement Studio Network Variable .NET Library section in the


DataSocket

The Measurement Studio DataSocket .NET class library is in the

NationalInstruments.Net

namespace. Use the DataSocket class library to transfer live measurement data over the Internet or an intranet, between applications on the same computer, and to and from files. Use the classes in the DataSocket class library to perform the following operations:

• Read and write data between different data sources and targets.

• Use a single, simple API to communicate with several types of servers, including DataSocket Servers ( dstp: ), Web servers ( http: ), file



Chapter 2 Measurement Studio .NET Class Libraries transfer protocol servers ( ftp: ), file systems ( file: ), and OLE for

Process Control ( opc: ) servers.

• Specify data sources and targets using a URL, the same way you access

Web pages in a Web browser.

• Use DataSocket Transfer Protocol (DSTP) to exchange different types of data.

• Expose DataSocket data items as data sources that you can bind to properties of a Windows Forms control.

• Interactively browse to quickly locate and select data items on other computers and servers.

Tip For more detailed information about the DataSocket class library, refer to the Using the Measurement Studio DataSocket .NET Library section in the NI Measurement Studio

Help .

NI-488.2

The Measurement Studio NI-488.2 .NET class library is in the

NationalInstruments.NI4882

namespace. This class library is included when you install the NI-488.2 driver. The NI-488.2 driver is available at ni.com/downloads . The NI-488.2 class library includes a set of classes for communicating with GPIB instruments, controlling GPIB devices, and acquiring GPIB status information. Use this library to design code that communicates with and controls instruments on a GPIB interface.

Use the NI-488.2 class library to configure and communicate with GPIB devices using the Device and Board classes.

Tip For more information about the NI-488.2 class library, refer to the Using the

Measurement Studio NI-488.2 .NET Library topic in the NI Measurement Studio Help .

For more information about GPIB visit ni.com/gpib .

NI-DAQmx

The Measurement Studio NI-DAQmx .NET class library is in the

NationalInstruments.DAQmx

namespace. This class library is included when you install the NI-DAQmx driver. The NI-DAQmx driver is available at ni.com/downloads . Use the NI-DAQmx class library to communicate with and control NI data acquisition (DAQ) devices.

Note Some DAQ devices are not currently supported by the NI-DAQmx driver. Refer to the NI-DAQ Readme for a complete listing of supported hardware.


2-16 ni.com


Use the NI-DAQmx class library to perform the following types of tasks:

• Analog signal measurement

• Analog signal generation

• Digital I/O

• Counting and timing

• Pulse generation

• Signal switching

Tip For more information about the NI-DAQmx class library, refer to the Using the

Measurement Studio NI-DAQmx.NET Library topic in the NI Measurement Studio Help .

For more information about DAQ, visit ni.com/dataacquisition .

NI-SCOPE

The .NET class libraries for NI-SCOPE include .NET APIs for NI-Scope,

NI-TClk, and NI-ModInst instrument drivers. These class libraries provide a .NET interface to the underlying driver API. You can use the .NET class libraries to create and configure NI-SCOPE components programmatically and at design time.

Tip For further information on NI-SCOPE .NET driver support and to download the

NI-SCOPE .NET class libraries, refer to NI-SCOPE .NET Driver Support at NI Developer

Zone, ni.com/devzone .

NI-VISA

The Measurement Studio NI-VISA .NET class library is in the

NationalInstruments.VisaNS

namespace. This class library is included when you install the NI-VISA driver. The NI-VISA driver is available at ni.com/downloads . The NI-VISA class library includes a set of classes that provides a rich, object-oriented interface to the NI-VISA driver. Use this library to quickly create bus-independent or bus-specific instrument control applications.

The NI-VISA class library supports formatted I/O operations, locking, event handling, and interface-specific extensions. With this class library you can access the functionality available in NI-VISA for communicating with message-based and register-based instruments using the following interfaces:

• GPIB

• IEEE 1394




• PXI

• Serial (RS-232 and RS-485)

• TCP/IP

• USB

• VXI

Tip For information about creating a Measurement Studio NI-VISA application using the

Instrument I/O Assistant, refer to the Creating an Instrument Control Application

section

in Chapter 4, Measurement Studio Integrated Tools and Features or the

Walkthrough:

Creating a Measurement Studio Instrument I/O Application

in Chapter 5, Getting Started with Measurement Studio . For more information about NI-VISA, visit

ni.com/visa .

User Interface

The Measurement Studio user interface controls are in the Windows Forms and Web Forms .NET class libraries. The following sections list the functionality included with the Measurement Studio Windows Forms and

Web Forms controls.

Refer to Table 2-2 for the UI controls provided by Measurement Studio.

Table 2-2. Measurement Studio User Interface Controls

User Interface Controls

Waveform graph

Scatter graph

Digital waveform graph

Complex graph

Legend

Knob

Gauge

Meter

Slide

Thermometer

Tank

Windows Forms

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User Interface Controls

Numeric edit

Switch

LED

Property editor

Array controls

AutoRefresh control

InstrumentControlStrip control

Table 2-2. Measurement Studio User Interface Controls (Continued)

Windows Forms

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Web Forms

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Windows Forms Controls

The Windows Forms .NET class library is in the

NationalInstruments.UI.WindowsForms

namespace. The Windows

Forms class library encapsulates the following Measurement Studio user interface controls:

• Waveform graph

• Scatter graph

• Digital waveform graph

• Complex graph

• Legend

• Knob

• Gauge

• Meter

• Slide

• Thermometer

• Tank

• Numeric edit

• Switch

• LED

• Property editor

• Array controls




Use this class library to add measurement-specific user interface controls to your application. You can configure the controls programmatically at design time, through the Properties window in the Windows Forms

Designer, or at run time with the property editor control. The following sections describe each of the Measurement Studio Windows Forms user interface controls.

Tip For more information about using the .NET user interface controls, refer to the Using the Measurement Studio Windows Forms .NET Controls section in the NI Measurement

Studio Help .

Waveform Graph and Scatter Graph Controls

Use the Measurement Studio waveform graph and scatter graph controls, as shown in Figure 2-1, to display two-dimensional data on a Windows Forms user interface. Use the waveform graph to display two-dimensional linear data. You explicitly specify each value in one dimension and provide an initial value and interval to implicitly specify the values in the other dimension. Use the scatter graph to display two-dimensional linear or nonlinear data: you explicitly specify each value in both dimensions.


Figure 2-1. Waveform Graph Windows Forms Control with Cursors and

Scatter Graph Windows Forms Control with XY Point Annotation; Both Graphs Have

Corresponding Legends

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With the waveform graph and scatter graph controls and the classes that interface with the controls, you can perform the following operations:

Plot Operations

• Plot and chart arrays of double-precision floating point values, analog waveforms, and complex waveforms.

• Configure a graph to contain multiple plots to show separate but related data on the same graph.

• Draw lines or fills from a plot to an X value, Y value, or another plot.

• Specify plots in the scatter graph control as X and Y data. Specify plots in the waveform graph control as X or Y data and optionally with date and time scaling.

• Use the extensible plot and plot area drawing capabilities and events to customize the graph appearance.

• Use plot data tooltips to display X and Y coordinates when a user hovers the mouse over a data point.

• Create custom point and line styles for plots.

• Specify anti-aliased plots for plot lines.

• Calculate and display error bands.

Axis Operations

• Configure a graph to include multiple axes or independent ranges so that plot data fits the graph plot area.

• Configure the axis modes to: fixed; autoscaling, including autoscaling based on the visible data only; strip chart; or scope chart.

• Use logarithmic axes with configurable bases.

• Interactively change the range of an axis and invert the axis at run time by clicking on the axis end labels.

• Display origin lines.

• Display captions on the axis.

• Display grid lines.

• Position the axis to display on one or both sides of the graph’s plot area.

• Configure major, minor, and custom divisions and origin lines.




Cursor Operations

• Use cursors to identify key points in plots and the plot area.

• Configure cursor snap modes to be fixed, floating, nearest point, or to plot.

• Use cursor labels to display X and Y data coordinates in a customized format that the cursor crosshair points to, and customize the text font and colors of the label.

• Create custom point and line styles for cursors.

• Interactively move the cursor by clicking and dragging the vertical or horizontal crosshair or the center of the cursor.

• Programmatically move the cursor to previous or next position or to a specified coordinate.

Annotation Operations

• Configure text labels, arrows, and drawing shapes to annotate a point anywhere in the plot area of the graph.

• Configure range area, text labels, and arrows to annotate a range in the plot area of the graph.

• Show tooltips configured to display data or other custom text.

Additional Operations

• Pan and zoom interactively, as well as programatically.

• Copy the graph as a BMP, GIF, JPEG, or PNG image to the clipboard or a file.

• Perform hit testing of mouse cursor coordinates.

• Bind a plot to a data source on the waveform graph.

Tip For more information about using the waveform and scatter graph controls, refer to the Using the Measurement Studio Windows Forms Scatter and Waveform Graph .NET

Controls section in the NI Measurement Studio Help .


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Digital Waveform Graph Control

Use the Measurement Studio digital waveform graph control, as shown in

Figure 2-2, to display DigitalWaveform data on a Windows Forms user interface.

Figure 2-2. Digital Graph Windows Forms Control

With the digital waveform graph control and the classes that interface with the control, you can perform the following operations:

Plot Operations

• Plot digital waveform data. Data values can represent up to eight different digital states.

• Configure plot labels on the y-axis.

• Configure plot templates to customize plots that are implicitly created from plotted data.

• Specify anti-aliased digital plots.

• Expand and collapse signal plots interactively or programmatically.

• Display tooltips.




Waveform Sample and Signal State Operations

• Simultaneously display waveforms and signals or display signals only.

• Create custom waveform sample and signal state styles.

• Configure the appearance of sample and state labels.

• Create custom waveform sample and signal state labels.

Axis Operations

• Configure the axis modes to fixed, exact autoscaling, or loose autoscaling.



• Display grid lines.


• Configure major, minor, and custom divisions.


• Display data in sample or time mode.


• Pan with scroll bars.

• Configure the style and mode of scroll bars.

• Create custom scroll bars.

• Pan and zoom interactively and programmatically.


Tip For more information about using the digital waveform graph control, refer to the

Using the Measurement Studio Windows Forms Digital Waveform Graph .NET Control section in the NI Measurement Studio Help .


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Complex Graph Control

Use the Measurement Studio complex graph control, as shown in

Figure 2-3, to display ComplexDouble data on a Windows Forms user interface. A ComplexDouble consists of a real part and an imaginary part.

You can use a waveform graph to plot complex waveform data.

Figure 2-3. Complex Graph Windows Forms Control

With the complex graph control and the classes that interface with the control, you can perform the following operations:

Plot Operations

• Plot and chart ComplexDouble data.




• Configure the plot to display arrows. The arrows indicate the direction of the complex data.




• Display tooltips.




Axis Operations




• Display origin lines and grid lines.






• Configure cursor snap modes to be fixed, floating, nearest point, or to plot.

• Use cursor labels to display X and Y data coordinates that the cursor crosshair points to, and customize the text font and colors of the label.


• Configure the graph to display cursors that are used to determine the real, imaginary, magnitude, and phase data coordinates of a point on the plot area.




• Annotate points and ranges of real, imaginary, and magnitude values.

• Annotate and label a range of magnitude values for a particular phase.


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• Pan and zoom interactively.


Tip For more information about using the complex graph control, refer to the Using the

Measurement Studio Windows Forms Complex Graph .NET Control section in the


Legend Control

Use the Measurement Studio legend control, as shown in Figure 2-1, to display symbols and descriptions for a specific set of elements of another object, such as the plots or cursors of a graph. When you associate the legend control with another object, any changes you make to that object are automatically reflected in the legend. For example, if you associate the legend control with the plots of a graph, any changes you make in the plots collection editor are automatically reflected in the legend.

Tip For more information about using the legend control, refer to the Using the

Measurement Studio Windows Forms Legend .NET Control section in the NI Measurement

Studio Help .

Numeric Controls

Use the Measurement Studio numeric controls to display numerical information, on a Windows Forms user interface, with the look of scientific instruments. The numeric controls include a knob, gauge, meter, slide, thermometer, and tank. The following sections describe operations available with the controls and the classes that interface with them.

With all of the numeric controls and the classes that interface with them, you can perform the following operations:

• Configure the scale to be linear or logarithmic and toggle the visibility of the scale.

• Fill the scale and configure the range, color, dimensions, and style of the fill.

• Connect to the Measurement Studio .NET numeric edit control so that if you change the value of one control, it changes the value of the other control.

• Customize the appearance of the control using 3D lab styles or classic

2D styles and change the color and length of ticks and labels.




• Configure the format of value labels to engineering or date/time.

• Display tooltips reflecting the current value of the pointer.

• Interactively change the value of the control by clicking or dragging and moving the pointer with the mouse.


• Programmatically move the pointer to previous or next value.


• Specify the image format of the control as BMP, GIF, JPEG, or PNG.

Use the Measurement Studio knob, gauge, and meter controls, as shown in

Figure 2-4, to input and display numeric data on your user interface.

Figure 2-4. Knob, Gauge, and Meter Windows Forms Controls

With the knob, gauge, and meter controls and the classes that interface with the controls, you can perform the following operations:

• Specify the start and sweep angle of the arc programmatically or from the Properties window.

• Use automatic division spacing, custom divisions, and invert the scale.


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Use the Measurement Studio slide, tank, and thermometer controls, as shown in Figure 2-5, to input and display numeric data on your interface.

Figure 2-5. .NET Slide, Tank, and Thermometer Controls

With the slide, tank, and thermometer controls and the classes that interface with them, you can perform the following operations:

• Fill to the minimum or maximum value of the scale.

• Position the scale horizontally with left, right, or both and position the scale vertically with top, bottom, or both.

Tip For more information about using the Windows Forms knob, gauge, meter, slide, tank, or thermometer controls, refer to the Knob , Gauge , Meter , Slide , Tank , or

Thermometer Class sections in the NI Measurement Studio Help .

Numeric Edit Control

Use the Measurement Studio numeric edit control, as shown in Figure 2-6, to display numeric values and to provide a way by which end users can edit numeric values. Typically, you use a numeric edit control to input or display double numerical data instead of using a Windows Forms TextBox or NumericUpDown control.

Figure 2-6. Numeric Edit Windows Forms Control




With the numeric edit control and the classes that interface with the control you can perform the following operations:

• Use up and down buttons for easy incrementing and decrementing.

• Perform range checking.

• Set the minimum range value to negative infinity and the maximum range value to positive infinity.

• Create custom formats or use built-in numeric formats including generic, engineering, and simple double. You can use these numeric formats with other Measurement Studio user interface controls, such as the waveform graph and numeric pointer controls.

• Connect to a Measurement Studio numeric control so that if you change the value of one control, it changes the value of the other control.

• Set the coercion mode property to discrete or continuous values. This property configures the control to allow entry or display of either a discrete set of values or any value.

• Set the interaction mode to keyboard and mouse, keyboard only, mouse only, or none.

Tip For more information about using the Windows Forms numeric edit control, refer to the NumericEdit Class section in the NI Measurement Studio Help .

Switch and LED Controls

Use the Measurement Studio switch and LED controls as Boolean controls on a Windows Forms user interface. You typically use a switch control, as shown in Figure 2-7, to receive and control Boolean input on an application user interface.

Figure 2-7. Switch Windows Forms Control in Vertical Toggle 3D Style


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You typically use an LED control, as shown in Figure 2-8, to indicate a

Boolean value on an application user interface.

Figure 2-8. LED Windows Forms Control in Square 3D Style

With the switch and LED controls and the classes that interface with the controls, you can perform the following operations:

• Receive notification before or after the state of the control changes.

• Configure how the control behaves when you click it with the mouse or press the spacebar when the control has focus.

• Configure the appearance of the control.

• Make the control background transparent.

• Configure the LED control to blink while it is on or off and configure the rate at which the LED control blinks.

Tip For more information about using the switch and LED controls, refer to the Using the

Measurement Studio Windows Forms Switch and LED .NET Controls section in the





Property Editor Control

Use the Measurement Studio property editor control, as shown in

Figure 2-9, to configure properties for Windows Forms controls at run time.


Figure 2-9. Property Editor Windows Forms Control for the Knob Control

Scale Arc Property

With the property editor control and the classes that interface with the control, you can perform the following operations:

• Edit any .NET type at run time, including collections.

• Edit expandable properties that represent nested properties of another object, such as major divisions of an axis.

• Display custom editors and type converters for properties.

• Connect to a Windows Forms control so that if you change the value of a property of the control, the Property Editor updates to reflect the change.

• Configure the display mode as a visual representation of the value, text-only, or both.

• Set the interaction mode to edit values or indicator.

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Tip For more information about using the property editor control, refer to the Using the

Measurement Studio Property Editor Control topic in the NI Measurement Studio Help .

Windows Forms Array Controls

You can create an array of Measurement Studio controls that behave as a single unit. For example, you can use these array controls to visualize and control ports of a digital line or values of an array. Measurement Studio includes switch, LED, and numeric edit array controls. You can create control arrays of other controls if those controls meet the constraints of the generic type parameter TControl .

Switch and LED Array Controls

Use the Measurement Studio switch and LED array controls as an array of

Boolean controls on a Windows Forms user interface. You typically use a switch array control, as shown in Figure 2-10, to control ports of a digital line or values of an array. You typically use an LED array control, as shown in Figure 2-10, to visualize ports of a digital line or values of an array.

Figure 2-10. Switch and LED Array Controls

With the switch and LED array controls and the classes that interface with the controls, you can perform the following operations:

• Set values by passing an array of data.

• Modify the number of controls displayed based on the length of the specified values.







• Make the control background transparent.

• Configure the LED controls to blink while they are on or off and configure the rate at which the LED controls blink.

• Configure the layout of the control to be horizontal or vertical.

• Bind the value of the control to a data source.

• Mark an array of Boolean controls so that only one can be true at a time.

Tip For more information about using the switch and LED array controls, refer to the

Using the Measurement Studio Control Array .NET Controls topic in the NI Measurement

Studio Help .

Numeric Edit Array Control

Use the Measurement Studio numeric edit array control, as shown in

Figure 2-11 to control and visualize values of an array of double values.

With the numeric edit array control and the classes that interface with the control you can perform the following operations:


Figure 2-11. Numeric Edit Array control

• Set values by passing an array of data.

• Modify the number of controls displayed based on the length of the array of values you specify.

• Use up and down buttons for easy incrementing and decrementing.



• Create custom formats or use built-in numeric formats including generic, engineering, and simple double.

• Connect to a numeric control so that if you change the value of one control, it changes the value of the other control.


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• Set the interaction mode to keyboard and mouse, keyboard only, mouse only, or none.

• Use the edit box to select text programmatically and to validate text values.

• Configure the layout of the control to be horizontal or vertical.

• Bind the value of the control to a data source.

Tip For more information about using the numeric edit array control, refer to the Using the Measurement Studio Control Array .NET Controls topic in the NI Measurement Studio

Help .

InstrumentControlStrip Control

You can use the InstrumentControlStrip control as a toolbar for editing property values of another control through the associated editors at run time. For example, you can populate the InstrumentControlStrip with

ToolStripPropertyEditor items that edit property values of a waveform graph through the associated editors at run time. The editor displayed by the ToolStripPropertyEditor is the same editor that displays when you edit the property at design time.




Figure 2-12. InstrumentControlStrip Control

Tip For more information about the InstrumentControlStrip control, refer to Using the

Measurement Studio Windows Forms Instrument Control Strip .NET Control topic in the



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ASP.NET Web Forms Controls

The Measurement Studio ASP.NET user interface controls are in the Web

Forms .NET class library. The Web Forms .NET class library is in the

NationalInstruments.UI.WebForms

namespace. The Web Forms class library encapsulates the following Measurement Studio user interface controls:

• Waveform graph

• Scatter graph

• Digital waveform graph

• Complex graph

• Legend

• Knob

• Gauge

• Meter

• Slide

• Thermometer

• Tank

• Numeric edit

• Switch

• LED

• AutoRefresh

Note All Measurement Studio ASP.NET Web Forms controls for Visual Studio 2008 are designed to work with ASP.NET AJAX controls. The Measurement Studio ASP.NET Web

Forms controls for Visual Studio 2005 are not designed to work with Microsoft ASP.NET

AJAX controls.

Use this class library to add measurement-specific user interface controls to your Web application. You can configure the controls programmatically at design time or through the Properties window in the Web Forms

Designer. The following sections describe each of the Measurement Studio

Web Forms user interface controls.




Waveform Graph and Scatter Graph Controls

Use the Measurement Studio waveform graph and scatter graph controls, as shown in Figure 2-13, to display two-dimensional data on a Web-based user interface. Use the waveform graph to display two-dimensional linear data. You explicitly specify each value in one dimension and provide an initial value and interval to implicitly specify the values in the other dimension. Use the scatter graph to display two-dimensional linear or nonlinear data: you explicitly specify each value in both dimensions.


Figure 2-13. Waveform Graph and Scatter Graph Web Forms Controls;

Both Graphs Have Corresponding Legends

With the waveform graph and scatter graph controls and the classes that interface with the controls, you can perform the following operations:

Plot Operations

• Plot and chart arrays of double-precision floating point values, analog waveforms, and complex waveforms.


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• Specify plots in the scatter graph control as X and Y data. Specify plots in the waveform graph control as X or Y data and optionally with date and time scaling.





• Configure plot to specify how data is saved and restored across HTTP requests.

Axis Operations



• Use logarithmic axes with configurable bases.





• Configure cursor snap modes to be floating, nearest point, or to plot.

• Use cursor labels to display X and Y data coordinates in a customized format that the cursor crosshair points to, and customize the text font and colors of the label.











• Zoom interactively as well as programatically.


Tip For more information about using the waveform and scatter graph controls, refer to the Using the Measurement Studio Web Forms Scatter and Waveform Graph .NET Controls section in the NI Measurement Studio Help .

Digital Waveform Graph Control

Use the Measurement Studio digital waveform graph control, as shown in

Figure 2-14, to display DigitalWaveform data in an ASP.NET Web application.


Figure 2-14. Digital Waveform Graph Web Forms Control

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With the digital waveform graph control and the classes that interface with the control, you can perform the following operations:

Plot Operations

• Plot digital waveform data, including digital signal state data and timing information.

• Configure plot labels on the y-axis.

• Configure plot templates to customize plots that are implicitly created from plotted data.

• Specify anti-aliased digital plots.

• Expand and collapse signal plots interactively as well as programmatically.

Waveform Sample and Signal State Operations

• Simultaneously display waveforms and signals or display signals only.

• Create custom waveform sample and signal state styles.

• Configure the appearance of sample and state labels.

• Create custom waveform sample and signal state labels.

Axis Operations

• Configure the axis modes to fixed, exact autoscaling, or loose autoscaling.


• Display captions on the axis and grid lines.


• Configure major, minor, and custom divisions.


• Display data in sample or time mode.

• Configure the style and mode of scroll bars.

• Create custom scroll bars.

• Zoom interactively as well as programmatically.





Tip For more information about using the digital waveform graph control, refer to the

Using the Measurement Studio Web Forms Digital Waveform Graph .NET Control section in the NI Measurement Studio Help .

Complex Graph Control

Use the Measurement Studio complex graph control, as shown in

Figure 2-15, to display ComplexDouble data on a ASP.NET Web application. A ComplexDouble consists of a real part and an imaginary part. You can use a waveform graph to plot complex waveform data.


Figure 2-15. Complex Graph Web Forms Control

With the complex graph control and the classes that interface with the control, you can perform the following operations:

Plot Operations

• Plot and chart ComplexDouble data.




• Configure the plot to display arrows. The arrows indicate the direction of the complex data.

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• Configure plot to specify how data is saved and restored across HTTP requests.

Axis Operations




• Display origin lines, captions on the axis, and grid lines.





• Configure cursor snap modes to be floating, nearest point, or to plot.

• Use cursor labels to display real, imaginary, magnitude, or phase data that the cursor crosshair points to, and customize the text font and colors of the label.










• Annotate and label a magnitude value.

• Annotate and label a range of magnitude values for a particular phase.


• Zoom interactively as well as programmatically.


Tip For more information about using the complex graph control, refer to the Using the

Measurement Studio Web Forms Complex Graph .NET Control section in the


Legend Control

Use the Measurement Studio legend control, as shown in Figure 2-13, to display symbols and descriptions for a specific set of elements of another object, such as the plots or cursors of a graph. When you associate the legend control with another object, any changes you make to that object are automatically reflected in the legend. For example, if you associate the legend control with the plots of a graph, any changes you make in the plots collection editor are automatically reflected in the legend.

Tip For more information about using the legend control, refer to the Using the

Measurement Studio Web Forms Legend .NET Control section in the NI Measurement

Studio Help .

Numeric Controls

Use the Measurement Studio numeric controls to display numerical information in an ASP.NET Web application with the look of scientific instruments. The numeric controls include a knob, gauge, meter, slide, thermometer, and tank. The following sections describe operations available with the controls and the classes that interface with them.

With all of the numeric controls and the classes that interface with them, you can perform the following operations:

• Configure the scale to be linear or logarithmic and toggle the visibility of the scale.

• Fill the scale and configure the range, color, dimensions, and style of the fill.

• Connect to a Measurement Studio .NET numeric edit control so that if you change the value of one control, it changes the value of the other control.


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• Customize the appearance of the control using 3D lab styles or classic

2D styles and change the color and length of ticks and labels.

• Configure the format of value labels to engineering or date/time.



• Display tooltips reflecting the current value of the pointer.

• Interactively change the value of the control by clicking the pointer with the mouse.

• Programmatically move the pointer to previous or next value.

Use the Measurement Studio knob, gauge, and meter controls, as shown in

Figure 2-16, to input and display numeric data on your user interface.

Figure 2-16. Knob, Gauge, and Meter Web Forms Controls

With the knob, gauge, and meter controls and the classes that interface with the controls, you can perform the following operations:

• Specify the start and sweep angle of the arc programmatically or from the Properties window.

• Use automatic division spacing, custom divisions, and invert the scale.




Use the Measurement Studio slide, tank, and thermometer controls, as shown in Figure 2-17, to input and display numeric data on your interface.

Figure 2-17. Slide, Tank, and Thermometer Web Forms Controls

With the slide, tank, and thermometer controls and the classes that interface with them, you can perform the following operations:

• Fill to the minimum or maximum value of the scale.

• Position the scale horizontally with left, right, or both and position the scale vertically with top, bottom, or both.

Tip For more information about using the Web Forms knob, gauge, meter, slide, tank, or thermometer controls, refer to the Knob , Gauge , Meter , Slide , Tank , or Thermometer Class sections in the NI Measurement Studio Help .


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Use the Measurement Studio numeric edit control, as shown in

Figure 2-18, to display numeric values and to provide a way by which end users can edit numeric values. Typically, you use a numeric edit control to input or display double numerical data instead of using a Web Forms

TextBox control.

Figure 2-18. Numeric Edit Web Forms Control

With the numeric edit control and the classes that interface with the control you can perform the following operations:



• Create custom formats or use built-in numeric formats including generic, engineering, and simple double. You can use these numeric formats with other Measurement Studio user interface controls, such as the waveform graph and numeric pointer controls.

• Connect to a Measurement Studio numeric control so that if you change the value of one control, it changes the value of the other control.


• Validate and format data without posting back to the Web server.

Tip For more information about using the Web Forms numeric edit control, refer to the

NumericEdit Class section in the NI Measurement Studio Help .




Switch and LED Controls

Use the Measurement Studio switch and LED controls as Boolean controls in an ASP.NET Web application. You typically use a switch control to receive and control Boolean input in an ASP.NET Web application. You typically use an LED control to indicate a Boolean value on an ASP.NET

Web application. The switch and LED controls are shown in Figure 2-19.

Figure 2-19. Switch Web Forms Control in Vertical Toggle 3D Style and

LED Web Forms Control in Square 3D Style

With the switch and LED controls and the classes that interface with the controls, you can perform the following operations:




• Configure the LED control to blink while it is on or off and configure the rate at which the LED control blinks.

Tip For more information about using the switch and LED controls, refer to the Using the

Measurement Studio Web Forms Switch and LED .NET Controls section in the



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AutoRefresh Control

Use the AutoRefresh control to update a Web control or a group of Web controls on the client at a specified interval.

The AutoRefresh control uses the ASP.NET client callback architecture to update a control or a group of controls at a specified interval. The

AutoRefresh control sets up a timer inside the browser using Javascript.

When the timer elapses, the AutoRefresh updates the controls in the

AutoRefresh group. For down-level browsers, the controls update when the page posts back to the server. If the client browser supports client callbacks, the client-side script rendered by the AutoRefresh control uses a client callback to update the associated controls on the client without posting the page back to the server.

Note The AutoRefresh control is designed to work with the ASP.NET AJAX UpdatePanel and Timer controls in Visual Studio 2008.

AutoRefresh Callback

This feature provides a mechanism for updating the

RefreshManager.Enabled

and AutoRefresh.Interval

properties for AutoRefresh from within the AutoRefresh.Refresh

callback, allowing you to turn off the AutoRefresh or change the Interval during an asynchronous HTTP request without causing a postback.



3

Measurement Studio Visual C++

Class Libraries

This chapter provides overview information about the Visual C++ class libraries that are available with Measurement Studio. Measurement Studio

Visual C++ support for Visual Studio .NET 2003 and Visual Studio 2005 is the same, except where noted. Refer to the Using the Measurement Studio

Visual C++ Class Libraries section of the NI Measurement Studio Help for detailed information about these libraries.

Note Measurement Studio 8.5 support for Visual Studio 2008 does not include Visual

C++ class libraries.

Measurement Studio Visual C++ Class Library Overview

Measurement Studio provides libraries of MFC-based classes that you can use to develop complete measurement and automation applications in

Visual C++.

Measurement Studio includes the following Visual C++ class libraries:

• 3D Graph

• Analysis

• Common

• DataSocket

• Microsoft Excel Interface

• Microsoft Word Interface

• NI-488.2

• NI-DAQmx

• NI-Reports

• NI-VISA

• User Interface

• Utility



Chapter 3

Refer to the following sections for information about each Measurement

Studio Visual C++ class library.

ActiveX Controls in Visual C++

ActiveX controls are specialized COM servers that implement a specific set of interfaces. The Measurement Studio Visual C++ button, graph, knob, numeric edit, slide, and 3D graph are ActiveX controls. Measurement

Studio includes classes that provide native C++ interfaces to the ActiveX controls. For example, the CNiGraph class provides an interface to the

CWGraph ActiveX graph control.

The Measurement Studio classes that provide interfaces to the

Measurement Studio ActiveX controls simplify using ActiveX controls in

Visual C++ interfaces and programs. The features that simplify this process include overloaded functions, the ability to call the control from any thread, and automatic data type translations.

3D Graph Control

Use the Measurement Studio ActiveX 3D graph control, as shown in

Figure 3-1, to plot three-dimensional data. The 3D graph is included only in the Measurement Studio Enterprise and Professional packages.


Figure 3-1. ActiveX 3D Graph Control

With the Measurement Studio ActiveX 3D graph control and the classes that interface with the control, you can perform the following operations:

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Plot Operations

• Plot three-dimensional data, including curves and surfaces.

• Use multiple plot styles—point-line, line-point, hidden-line, contour, surface, surface-line, surface-contour, and surface-normal.

• Create multiple plots with individual properties, such as name, line and point style, width, and base value.

• Configure the control to render directly to OpenGL-enabled hardware accelerator cards.

• Bind the control to a DataSocket Server to enable automatic read and write functionality.


• Configure the axes using customizable ticks, labels, value pairs, and captions.

• Use legends and plane projections.

• Use cartesian, cylindrical, and spherical coordinate systems.

• Customize the control using color maps, transparency, and lighting.

• Display in orthographic and perspective views.

• Use built-in format styles for labels including scientific, symbolic engineering, scaling, time, and date.

• Rotate, pan, and zoom interactively.

Tip For information about easily creating graphs with the 3D graph control library, refer to the 3D Graph Visual C++ Class Library Overview topic in the NI Measurement Studio

Help .

Analysis

The Analysis class library includes a set of classes that provides various digital signal processing, signal filtering, signal generation, peak detection, and other general mathematical functionality. Use this library to analyze acquired data or to generate data.

The functionality included in the Analysis library varies based on the

Measurement Studio package you purchased. Refer to the following sections for information about the Standard, Professional, and Enterprise

Analysis class libraries.



Chapter 3

Standard Analysis

The Standard Analysis class library, which ships with Measurement Studio

Standard Edition, includes the sawtooth, sine, square, triangle, and basic function wave generators.

Professional Analysis

The Professional Analysis class library, which ships with Measurement

Studio Professional Edition, includes the Standard Analysis functionality as well as the following functionality:

• Bessel, Chebyshev, Inverse Chebyshev, Windowed, Kaiser, and

Elliptic Low, High, Bandpass, and Bandstop filters

• Signal processing functions such as convolution, deconvolution, correlation, decimation, integration, and differentiation

• FFT, Inverse FFT, Real FFT, Fast Hartley, Inverse Fast Hartley, Fast

Hilbert, Inverse Fast Hilbert, DST, Inverse DST, DCT, and Inverse

DCT transformations

• Linear algebra functions such as determinant, check positive definiteness, calculate dot product, and other various matrix methods

• Scaled and unscaled windowing classes

• Common statistical functions such as mean, median, mode, and variance

• Exponential, linear, and polynomial curve fitting functions

• Signal generation functions

Enterprise Analysis

The Enterprise Analysis class library, which ships with Measurement

Studio Enterprise Edition, includes the Standard and Professional Analysis functionality as well as the following advanced functionality:

• EquiRipple filters

• Linear algebra functions such as forward and back substitution,

LU factorization, Cholesky factorization, Schur decomposition, and

Hessenberg decomposition

• Probability and analysis of variance

• Sinc, impulse, pulse, ramp, and chirp patterns

• General least squares fit, power fit, log fit, Gauss Fit, cubic spline fit, and interpolation functions

• Special functions


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Refer to Table 3-1 to determine the type of measurements available in the

Professional and Enterprise Analysis Visual C++ libraries.

Table 3-1. Analysis Visual C++ Library Measurement Types Included in the

Professional and Enterprise Packages

Analysis Visual C++ Library Professional Package

Measurements


✔

✔

AC and DC Estimator

Amplitude and Phase

Spectrum

Auto Power Spectrum

Cross Power Spectrum

Harmonic Analyzer

Impulse Response Function

Network Functions (avg)

Power and Frequency Estimate

Scaled Time Domain Window

Spectrum Unit Conversion

Transfer Function

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

Signal Generation

✔

Arbitrary Wave

Chirp Wave

Gaussian White Noise

Impulse Pattern

Pulse Pattern

Ramp Pattern

Sawtooth Wave

Sinc Pattern

Sine Pattern

Sine Wave

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔



Chapter 3

Analysis Visual C++ Library

Square Wave

Triangle Wave

Force Window

Gauss Window

Windows


Professional and Enterprise Packages (Continued)

Uniform White Noise

Blackman Window

Blackman-Harris Window

Blackman-Nuttall Window

Cosine Tapered Window

Dolph-Chebyshev Window

Exact Blackman Window

Exponential Window

Flat Top Window

General Cosine Window

Hamming Window

Hanning Window

Kaiser-Bessel Window

Scaled Time Domain Windows

Symmetric Time Domain

Triangle Window


✔

✔

✔

Windowing

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔


✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

Bessel

Butterworth

✔

Filters

✔

✔

✔

✔


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Cascade

Chebyshev

Elliptic

Equiripple

FIR

FIR Windowed

IIR Cascade

IIR

Inverse Chebyshev

Kaiser

Autocorrelation

Convolution

Cross Power

Cross Correlation

Decimate

Deconvolution

Derivative x(t)

Discrete Cosine Transform

Discrete Sine Transform

Fast Hilbert Transform

Fast Hartley Transform

Integral x(t)

Inverse Real and Complex Fast

Fourier Transform (FFT)




✔

✔

✔

✔

✔

✔

✔

✔

✔

Signal Processing

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔


✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔



Chapter 3


Inverse Fast Hilbert Transform

Inverse Fast Hartley Transform

Peak Detection

Power Spectrum

Pulse Parameters

Real and Complex FFT

Threshold Peak Detector

Unwrap Phase




✔

✔

✔

✔

✔

✔

✔

✔

Linear Algebra


✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

Back Transform Eigen Vectors

Backward Substitution

Cholesky Factorization

Complex Back Transform

Eigen Vectors

Complex Cholesky

Factorization

Complex Determinant

Complex Dot Product

Complex Eigen Vectors and

Eigen Values

Complex General Eigen AB

Complex Hessenberg

Decomposition

Complex Inverse Matrix

Complex Linear Equations

Complex LU Factorization

Complex Matrix Balance

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔

✔


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Complex Matrix Condition

Number

Complex Matrix Norm

Complex Matrix Rank

Complex Outer Product

Complex Pseudo Inverse

Matrix

Complex QR Factorization

Complex QR Factorization with Pivot Matrix

Complex QR Factorization with Pivot Vector

Complex QZ Decomposition

Complex Schur

Decomposition


Equations (Multiple Right

Hand)


Equations (Single Right Hand)

Complex SVD Factorization

Complex Vector Norm

Determinant

Dot Product

Forward Substitution

General Eigen AB

Hessenberg Decomposition

Inverse Matrix


✔

✔

✔

✔

✔

✔

✔

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Chapter 3




Linear Equations

LU Factorization

Matrix Balance

Matrix Condition Number

Matrix Multiplication

Matrix Norm

Matrix Rank

Outer Product

Pseudo Inverse Matrix

QR Factorization


Matrix


Vector

QZ Decomposition

Schur Decomposition


(Multiple Right Hand)


(Single Right Hand)

Special Matrix

SVD Factorization

Test Positive Definite Matrix

Trace

Transpose

1D and 2D Array Arithmetic


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1D and 2D Linear Evaluation

1D and 2D Polynomial

Evaluation

1D Polar to Rectangular

1D Rectangular to Polar

Complex Number Arithmetic

Find Polynomial Roots

Scale 1D and 2D


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Exponential Fit

Exponential Fit Interval

Gauss Fit

Gauss Fit Interval

General Least Squares

Linear Fit

General Polynomial Fit

Goodness of Fit

Linear Fit

Linear Fit Interval

Logarithm Fit

Logarithm Fit Interval

Nonlinear Fit

Polynomial Fit

Power Fit

Power Fit Interval

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Chapter 3




Remove Outliers

Professional Package Enterprise Package

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Statistics

1D, 2D, and 3D ANOVA

Chi-Square Distribution erf(x) and erfc(x)

F-Distribution

Histogram

Inverse Chi-Square

Distribution

Inverse F-Distribution

Inverse Normal Distribution

Inverse T-Distribution

Mean

Median and Mode

Moment about Mean

Normal Distribution

Polynomial Interpolation

Root-Mean-Square (RMS)

Spline Interpolant

Spline Interpolation

Standard Deviation

T-Distribution

Variance

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Airy

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Professional Package Analysis Visual C++ Library

Bessel 1st

Bessel 2nd

Beta

Complimentary Gamma

Cosine Integral

Dawson’s Integral

Dilogarithm

Elliptic 1st

Elliptic 2nd

Exponential Integral

Factorial

Fresnel Integrals

Gamma

Gauss HyperGeometric

Hyperbolic Cosine Integral

Hyperbolic Sine Integral

Incomplete Beta

Incomplete Elliptic 1st

Incomplete Elliptic 2nd

Incomplete Gamma

Jacobian Elliptic Function

Kelvin 1st

Kelvin 2nd

Kummer

Logarithm of Factorial


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Chapter 3



Professional Package Analysis Visual C++ Library

Modified Bessel 1st

Modified Bessel 2nd

Parabolic Cylinder

Psi

Sine Integral

Spherical Bessel 1st

Spherical Bessel 2nd

Stirling

Struve

Tricomi

Zeta


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Tip For more information about analyzing or generating data with the Analysis class library, refer to the Analysis Visual C++ Class Library Overview topic in the

NI Measurement Studio Help . For more information about the functionality included in the

Analysis class library, visit ni.com/analysis and select Visual Basic, Visual Basic

.NET, C++, and C# with Measurement Studio .


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Common

The Measurement Studio Common Visual C++ class library provides data types and classes that other Measurement Studio Visual C++ class libraries use. The classes that are implemented natively in Visual C++ include the

CNiVector and CNiMatrix classes.

The Common class library includes the following data types:

• CNiScalarVector —Implements a vector object that contains scalar numbers.

• CNiScalarMatrix —Implements a matrix object that contains scalar numbers.

• CNiString —Extends the MFC CString class with streaming operators for a variety of data types and with various other string manipulation functions.

• CNiScalarVector —Implements a vector object that contains scalar numbers.

• CNiVariant —Extends the MFC COleVariant class with additional constructors and assignment operators for CNiComplex-, CNiVector-, and CNiMatrix-derived objects and with cast operators to convert

CNiVariant objects to a variety of other object types.

• CNiException —Extends the MFC CException class and serves as the base class for many Measurement Studio exceptions.

• CNiRegKey —Encapsulates the interface to the Windows registry. Use this class and related classes to open and create keys, get keys, and get values associated with those keys.

Tip For more detailed information about the Common class library, refer to the Common

Visual C++ Class Library Overview topic in the NI Measurement Studio Help .

DataSocket

Use the Measurement Studio DataSocket Visual C++ class library to transfer live measurement data over the Internet or an intranet, between applications on the same computer, and to and from files. Use the classes in the DataSocket Visual C++ class library to perform the following operations:

• Read and write data between different data sources and targets.

• Use a single, simple API to communicate with several types of servers, including DataSocket Servers ( dstp: ), Web servers ( http: ), file



Chapter 3 transfer protocol servers ( ftp: ), file systems ( file: ), and OLE for

Process Control ( opc: ) servers.

• Specify data sources and targets using a URL, the same way you access

Web pages in a Web browser.

• Use DataSocket Transfer Protocol (DSTP) to exchange different types of data.

• Interactively browse to quickly locate and select data items on other computers and servers.

Tip For more information about using DataSocket, refer to the DataSocket Visual C++

Class Library Overview topic in the NI Measurement Studio Help .

Microsoft Excel Interface

Use the Measurement Studio Excel Visual C++ class library to automatically create Excel spreadsheets and charts from within measurement and automation applications. Use the Microsoft Excel

Interface class library to perform offline processing of the measurement and automation data you acquire and analyze using other Measurement

Studio Visual C++ classes. This class library is included only in the

Measurement Studio Enterprise package.

Tip For more information about using the Measurement Studio Excel Visual C++ class library to create applications that present data in Microsoft Excel format, refer to the Microsoft Excel Interface Visual C++ Class Library Overview topic in the


Microsoft Word Interface

Use the Measurement Studio Microsoft Word Interface Visual C++ class library to automatically create Word documents from within measurement and automation applications. Use the Microsoft Word Interface class library to perform offline processing of the measurement and automation data you acquire and analyze using other Measurement Studio Visual C++ classes. This class library is included only in the Measurement Studio

Enterprise package.

Tip For more information about using the Measurement Studio Word Visual C++ class library to create applications that present data in Microsoft Word, refer to the Microsoft

Word Interface Visual C++ Class Library Overview topic in the NI Measurement Studio

Help .


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NI-488.2

Use the Measurement Studio NI-488.2 Visual C++ class library to communicate with and control instruments on a GPIB interface. This class library is included when you install the NI-488.2 driver. Use this class library to configure and communicate with GPIB devices using the

CNi4882Device and CNi4882Board classes.

You can use the NI-488.2 class library to create programs that interface with a device that is using GPIB and programs that interface with the GPIB device directly.

Tip For information about easily creating a Measurement Studio NI-488.2 application

using the Instrument I/O Assistant, refer to the Creating an Instrument Control Application

section of Chapter 4, Measurement Studio Integrated Tools and Features

. You can create

Measurement Studio NI-488.2 applications with the Instrument I/O Assistant in Visual

Studio .NET 2003 only. For more information about GPIB, visit ni.com/gpib .

NI-DAQmx

Use the Measurement Studio NI-DAQmx Visual C++ class library to communicate with and control an NI data acquisition (DAQ) device. This class library is included when you install the NI-DAQmx driver.

Note Some DAQ devices are not currently supported by the NI-DAQmx driver. Refer to the NI-DAQ Readme for a complete listing of supported hardware.

Use the NI-DAQmx class library to perform the following types of tasks:

• Analog signal measurement

• Analog signal generation

• Digital I/O

• Counting and timing

• Pulse generation

• Signal switching

Tip For information about easily creating an NI-DAQmx application using the DAQ

Assistant, refer to the Creating a Measurement Studio NI-DAQmx Application section of

Chapter 4, Measurement Studio Integrated Tools and Features

, or the Walkthrough:

Creating a Measurement Studio NI-DAQmx Application

section of Chapter 5, Getting

Started with Measurement Studio . For more information about DAQ, visit

ni.com/daq .



Chapter 3

NI-Reports

Use the Measurement Studio NI-Reports Visual C++ class library to generate printed reports from Measurement Studio Visual C++ applications. This class library is included only in the Measurement Studio

Enterprise package.

Tip For information about generating printed reports using the NI-Reports class library, refer to the NI-Reports Visual C++ Class Library Overview topic in the NI Measurement

Studio Help .

NI-VISA

The Measurement Studio NI-VISA Visual C++ class library includes

Visual C++ classes that provide an object-oriented interface to the

NI-VISA driver. This class library is included when you install the

NI-VISA driver. Use the NI-VISA class library to quickly create bus-independent and bus-specific instrument control applications.

The NI-VISA class library supports I/O operations, locking, event handling, and interface-specific extensions. With this class library, you can access the functionality available in NI-VISA for communicating with message-based and register-based instruments using the following interfaces:

• GPIB

• PXI

• Serial (RS-232 and RS-485)

• TCP/IP

• USB

• VXI

Tip For information about easily creating a Measurement Studio NI-VISA application using the Instrument I/O Assistant, refer to the

Creating an Instrument Control Application

section of Chapter 4, Measurement Studio Integrated Tools and Features , or the

Walkthrough: Creating a Measurement Studio Instrument I/O Application section of

Chapter 5, and Getting Started with Measurement Studio

. For more information about

NI-VISA, visit ni.com/visa .


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User Interface

Use the Measurement Studio User Interface Visual C++ class library to add user interface controls to your application. You can configure the user interface controls programmatically or through the property pages in the

Visual C++ resource editor. Measurement Studio includes the following

Visual C++ user interface controls:

• Button

• Graph

• Knob

• Numeric edit

• Slide

The following sections describe each of the Measurement Studio Visual

C++ user interface controls.

Button Control

Use the Measurement Studio ActiveX button control, as shown in

Figure 3-2, for different Boolean displays, such as on or off or true or false.

Typically, you use buttons to input or display Boolean information or initiate an action in a program. The CNiButton class provides the Visual

C++ interface to the ActiveX button control.

Figure 3-2. ActiveX Button Control

With the button control and the classes that interface with the control, you can perform the following operations:


• Configure how the button control appears using button styles. You can configure the button control to appear as a push button, LED, or switch.

• Bind properties to a DataSocket source or target. You use binding to read property values from a source and write property values to a target.



Chapter 3

Tip For more information about using the button control, refer to the Using the

Measurement Studio Button Visual C++ Control section in the NI Measurement Studio

Help .

Graph Control

Use the Measurement Studio ActiveX graph control, as shown in

Figure 3-3, to plot and chart two-dimensional data. The CNiGraph class provides the Visual C++ interface to the ActiveX graph control.

Figure 3-3. ActiveX Graph Control

With the graph control and the classes that interface with the control, you can perform the following operations:

Plot Operations

• Plot and chart data.


• Configure a graph to include multiple Y axes so that plot data fits the graph plot area.

• Use cursors and annotations to identify key points in plots and the plot area.


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Axis Operations

• Use the CNiAxis class to interface to a single axis of a graph control.

This feature allows you to modify the appearance and behavior of the axis.

• Automatically label axes with log or inverted numeric scales.

• Configure the axis modes for manual scaling or autoscaling.


• Configure cursor snap modes to be fixed, floating, nearest point, and to plot.

• Pan and zoom interactively.

• Configure the graph for fixed, strip, or scope charting.

• Customize the graph by using ticks, labels, and value pairs.


Tip For more information about easily using the graph control, refer to the Using the

Measurement Studio Graph Visual C++ Control section in the NI Measurement Studio

Help .

Knob Control

Use the Measurement Studio ActiveX knob control, as shown in

Figure 3-4, to display numerical information. The CNiKnob class provides the Visual C++ interface to the ActiveX knob control.

© National Instruments Corporation

Figure 3-4. ActiveX Knob Control with Knob, Dial, and Meter Styles

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Chapter 3

With the knob control and the classes that interface with the control, you can perform the following operations:

• Use different display styles—knobs, dials, and meters.

• Use multiple control pointers, each representing one scalar value.

A control pointer indicates the current value of the knob.

• Use the CNiAxis class to interface to a single axis of a knob control.

This feature allows you to modify the appearance and behavior of the axis.

• Automatically label axes with log or inverted numeric scales and continuous or discrete values.

• Customize the knob by using ticks, labels, and value pairs.


Tip For more information about easily using the knob control, refer to the Using the

Measurement Studio Knob Visual C++ Control section in the NI Measurement Studio

Help .


Use the Measurement Studio ActiveX numeric edit control, as shown in

Figure 3-5, to display numeric values and provide a way by which end users can edit numeric values. Typically, you use a numeric edit control to input or display numerical data instead of using a text box. The

CNiNumEdit class provides the Visual C++ interface to the ActiveX numeric edit control.


Figure 3-5. ActiveX Numeric Edit Control

With the numeric edit control and the classes that interface with the control, you can perform the following operations:

• Use built-in numeric format styles, including scientific, symbolic engineering, scaling, time, and date.



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Tip For more information about easily using the numeric edit control, refer to the Using the Measurement Studio Numeric Edit Visual C++ Control section in the NI Measurement

Studio Help .

Slide Control

Use the Measurement Studio ActiveX slide control, as shown in

Figure 3-6, to display numerical data. CNiSlide is the class that provides the Visual C++ interface to the ActiveX slide control.

Figure 3-6. ActiveX Slide Control

With the slide control and the classes that interface with the control, you can perform the following operations:

• Use different display styles—vertical, horizontal, tank, and thermometer.

• Use the CNiAxis class to interface to a single axis of a slide control.

This ability allows you to modify the appearance and behavior of the axis.

• Use multiple control pointers, each one representing one scalar value.

• Automatically label axes with log or inverted numeric scales and continuous or discrete values.

• Customize the slide by using ticks, labels, and value pairs.


Tip For more information about easily using the slide control, refer to the Using the

Measurement Studio Slide Visual C++ Control section in the NI Measurement Studio Help .



Chapter 3

Utility

Utility Class

CNiFile

CNiSound

CNiSystem

CNiSystemTrayIcon

Use the Measurement Studio Utility Visual C++ class library to easily access Windows operating system functionality. Table 3-2 lists classes in the Utility class library and their functionality.

Table 3-2. Utility Class Names and Functionalities

Functionality

CNiFile extends the MFC CStdioFile class by adding streaming operators for standard Visual C++ data types. In addition, a variety of class static functions add the ability to manipulate file, path, directory, and drive attributes.

CNiSound encapsulates an interface for generating synchronous and asynchronous tones at specific frequencies.

CNiSystem provides the following functionality:

• Getting and setting system preferences

• Displaying help files

• Getting input for the keyboard

CNiSystemTrayIcon encapsulates the interface to the system tray area that displays changes in the status of an application. The

CNiSystemTrayIcon class includes the following features:

• Icons—You can place an icon in the system tray to notify the user of changes in an application status.

• String tooltips—You can associate a string tooltip with an icon and display the tooltip when the user hovers over the icon.

• Shortcut menus—You can associate a shortcut menu with an icon and display the shortcut menu when the user right-clicks the icon.

• Overridable event handling.


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Utility Class

CNiTempFile

CNiTimer

Table 3-2. Utility Class Names and Functionalities (Continued)

Functionality

CNiTempFile extends the functionality of CNiFile to add temporary file creation and manipulation.

CNiTimer objects use the Windows multimedia timer to generate high-resolution, asynchronous tick events. Respond to tick events when you want to perform an action at a discrete interval.

Additionally, you can count the tick events to calculate elapsed time. The CNiTimer class also contains static functions you can use to delay for a period of time or to determine elapsed time between two points in your program.

Tip For more information about using the Utility class library, refer to the Utility Visual

C++ Class Library Overview section in the NI Measurement Studio Help .



4

Measurement Studio Integrated

Tools and Features

When you use Measurement Studio in the Visual Studio environment, you have access to measurement and automation tools and features for Visual

Basic .NET, Visual C#, ASP.NET, and Visual C++. These integrated tools and features are designed to help you quickly and easily build measurement and automation applications. These integrated tools and features are included in support for both Visual Studio 2005 and Visual Studio 2008.

This chapter includes the following sections to help you develop applications with Measurement Studio:

• Measurement Studio Menu

•

Creating a Measurement Studio Project

•

Adding or Removing Measurement Studio .NET Class Libraries

•

Creating a Measurement Studio NI-DAQmx Application

•

Creating an Instrument Control Application

•

Selecting a Measurement Studio Parameter Value

•

Using the Instrument Driver Wizard

Refer to the Developing with Measurement Studio section in the

NI Measurement Studio Help for more information about the functionality of these tools and features.

Measurement Studio Menu

The Measurement Studio Menu provides an easy way to access the following National Instruments resources and tools:

• Parameter Assistant —Use the Measurement Studio Parameter

Assistant to discover and insert valid parameter values for various

Measurement Studio class libraries, such as NI-DAQmx, NI-488.2, and NI-VISA methods. The Parameter Assistant is available only if you have Measurement Studio class libraries installed that use parameter values.



Chapter 4 Measurement Studio Integrated Tools and Features

• Add/Remove .NET Class Libraries Wizard —Use the Measurement

Studio Add/Remove Class Libraries wizard to add or remove

Measurement Studio class libraries or assemblies in existing Visual

Basic .NET, Visual C#, or Visual C++ projects.

• Refresh Project License File —Use the Refresh Project License File to update the licenses.licx

file in a Measurement Studio project to the currently referenced Measurement Studio assemblies. The Refresh

Project process works by going through the licenses.licx

file line by line for the active project and removing each Measurement Studio licensed type that matches the Measurement Studio

PublicKeyToken . After all Measurement Studio licensed types are removed from the licenses.licx file, the current Measurement

Studio licensed types that are referenced by the project are added to the licenses.licx

file. This ensures all Measurement Studio licensed types used by the project are added to the licenses.licx

file.

• Add 64-Bit Protection to Project —Updates your project’s platform target to x86 and updates your project to protect it from build error

LC0000. Refer to Using Measurement Studio on 64-Bit Operating

Systems and Protecting Your Project from LC0000 Build Error in the

NI Measurement Studio Help for more information. This menu item is only available in Visual Studio 2005 on a 64-bit Windows OS. Visual

Studio 2008 projects function correctly without this protection.

• Remove 64-Bit Protection from Project —Removes protection for build error LC0000 from your project. Refer to Using Measurement

Studio on 64-Bit Operating Systems and Protecting Your Project from

LC0000 Build Error in the NI Measurement Studio Help for more information. This menu item is only available in Visual Studio 2005 on a 64-bit Windows OS. Visual Studio 2008 projects function correctly without this protection.

• Update Measurement Studio Project References —Updates any outdated Measurement Studio references to the latest version installed on the system.

• NI Tools»Measurement & Automation Explorer (MAX) —Use

MAX to configure NI hardware; add new channels, interfaces, and tasks; execute system diagnostics; and view devices and instruments connected to the system. Select NI Tools»Measurement &

Automation Explorer (MAX) to access this menu item. The MAX menu option is available only if you have MAX installed.

• NI Tools»NI Spy —Use NI Spy to monitor, record, and display

National Instruments API calls made by instrument connectivity applications. Use NI Spy to quickly locate and analyze any erroneous

National Instruments API calls that an application makes and verify


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Chapter 4 Measurement Studio Integrated Tools and Features that the communication with an instrument is correct. Select

NI Tools»NI Spy to access this menu item. The NI Spy menu item is available only if you have NI Spy installed.

• NI Tools»Variable Manager —Use Variable Manager to create new processes and variables, delete existing processes and variables, start and stop processes, create variables with specific data types or the variant data type, allow multiple writers or restrict write access to a single client, and configure server buffering. Select NI Tools»Variable

Manager to access this menu item.

• NI Measurement Studio Help —Use the NI Measurement Studio

Help to access detailed Measurement Studio help, including function reference, walkthroughs, and conceptual topic documentation on developing with Measurement Studio.

• Measurement Studio Online Resources»Measurement Studio

Home Page —Use the Measurement Studio Web site at ni.com/mstudio to find Measurement Studio news, support, downloads, and evaluation software. Select Measurement Studio

Online Resources»Measurement Studio Home Page to access this menu item.

• Measurement Studio Online Resources»Instrument Driver

Network —Use the NI Instrument Driver Network at ni.com/idnet as a central resource for downloading, developing, and submitting instrument drivers. Select Measurement Studio Online

Resources»Instrument Driver Network to access this menu item.

• Measurement Studio Online Resources»Discussion Forums —Use the NI Discussion Forums at forums.ni.com

to participate in discussion forums and exchange code with measurement and automation developers around the world. Select Measurement Studio

Online Resources»Discussion Forums to access this menu item.

• Measurement Studio Online Resources»Search Technical

Support —Use NI Technical Support at ni.com/support to find support resources available for most products, including software drivers and updates, KnowledgeBase articles, product manuals, step-by-step troubleshooting wizards, conformity documentation, example code, tutorials and application notes, instrument drivers, discussion forums, and a measurement glossary. Select Measurement

Studio Online Resources»Search Technical Support to access this menu item.




• Measurement Studio Online Resources»NI Developer

Zone —NI Developer Zone, zone.ni.com

, provides access to online example programs, tutorials, technical news, and a Measurement

Studio Discussion Forum where you can participate in discussion forums for Visual Basic 6.0, Visual C++, and .NET Languages. Select

Measurement Studio Online Resources»NI Developer Zone to access this menu item.

• Patents —Use the Patents dialog box to view information about

NI patents.

• Licenses —Use the Licenses dialog box to view information about

NI licenses.

• About Measurement Studio —Use the Measurement Studio About box to view version information.

• Preferences —Use the Measurement Studio Preferences dialog box to configure Measurement Studio settings, such as conversion options and add-in preferences. Select Tools»Options to access this menu item.

Tip For more information about the resources included in the Measurement Studio Menu, refer to the Measurement Studio Menu topic in the NI Measurement Studio Help .

Creating a Measurement Studio Project

Measurement Studio includes class library and application templates that you can use to quickly create measurement applications with Visual Basic

.NET, Visual C#, ASP.NET, and Visual C++. Refer to the following sections, Walkthrough: Creating an Application with Windows Forms

Controls and Analysis or Walkthrough: Creating an Application with Web

Forms Controls and Analysis , for step-by-step instructions on how to create a Measurement Studio project. Use the Visual Studio New Project dialog box, as shown in Figure 4-1, to access these templates and to create projects. You can create the following projects in Measurement Studio:

• Measurement Studio Visual Basic .NET project

• Measurement Studio Visual C# project

• Measurement Studio ASP.NET project

• Measurement Studio Visual C++ project (Visual Studio 2005 only)

• Measurement Studio Visual C++ project with LabWindows/CVI libraries (Visual Studio 2005 only)


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Figure 4-1. New Project Dialog Box in Visual Studio 2005

Tip For more information about using project templates to create a new Measurement

Studio project, refer to the Creating a New Measurement Studio Project section in the


Note For information about converting Measurement Studio projects, refer to the

Converting Measurement Studio Projects section in the NI Measurement Studio Help .

Adding or Removing Measurement Studio .NET Class

Libraries

To add or remove Measurement Studio .NET class libraries from a project, use the Measurement Studio Add/Remove .NET Class Libraries wizard on the Measurement Studio menu. This wizard provides an interface, as shown in Figure 4-2, that you can use to select the Measurement Studio .NET class libraries you want to add to or remove from a project.




When you exit the wizard, the wizard adds or removes the appropriate references to or from the project, thus adding or removing the functionality associated with the class library.

Figure 4-2. Measurement Studio Add/Remove Class Libraries Wizard for

Visual Studio 2005

Tip For more information about using the Add/Remove .NET Class Libraries wizard to add or remove Measurement Studio .NET class libraries, refer to the Adding or Removing

Measurement Studio .NET Class Libraries section in the NI Measurement Studio Help .

Creating a Measurement Studio NI-DAQmx Application

To create a Measurement Studio NI-DAQmx application, use the DAQ

Assistant. The DAQ Assistant integrates into Visual Studio as a code designer. Use the Add New Item wizard to add an NI-DAQmx task to your project, and use the DAQ Assistant user interface, as shown in Figure 4-3, to interactively create and configure the NI-DAQmx task. The DAQ

Assistant automatically generates a Visual Basic .NET, Visual C#, or

Visual C++ (Visual Studio 2005 only) class that includes the functionality you configure in the user interface.


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Note The DAQ Assistant is available only if you have installed NI-DAQmx and either the

Measurement Studio Professional or Measurement Studio Enterprise package.

Refer to Chapter 5, the

Walkthrough: Creating a Measurement Studio

NI-DAQmx Application

section, for step-by-step instructions on how to create DAQ applications.


Figure 4-3. DAQ Assistant



The DAQ Assistant interactively assists you in performing the following operations:

• Creating an NI-DAQmx task class

• Configuring an NI-DAQmx task class

• Generating a Visual Basic .NET, Visual C#, or Visual C++ class that includes the functionality you configure in the user interface

• Generating code that uses an NI-DAQmx task class

• Using an NI-DAQmx task class in a project

• Generating a DAQ component that uses the task to provide appropriate operations for your measurement type.

Tip For more information about using the DAQ Assistant to create a Measurement Studio

NI-DAQmx application, refer to the Creating a Measurement Studio NI-DAQmx

Application section in the NI Measurement Studio Help .

Creating an NI-DAQmx User Interface

Using the Configure DAQ Component UI wizard, as shown in Figure 4-4, you can customize and preview a user interface and code for your task. The wizard also generates event handlers and code to acquire data and present it on your generated user interface.


Figure 4-4. Configure DAQ Component UI Wizard

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Tip For more information on how to create an NI-DAQmx user interface, refer to the

Using a .NET DAQ Component in a Project topic in the NI Measurement Studio Help .

Creating NI-DAQmx User Code in Visual C++

Note Measurement Studio 8.5 support for Visual Studio 2008 does not include support for

Visual C++.

You can create NI-DAQmx user code in Visual C++. The DAQmx User

Code wizard wraps the configured DAQmx task class in a user-friendly class and creates a dialog that provides an example of using the new class.

You can use the user code in two different ways. You can call the DoModal function on the new dialog class, or you can use the user-friendly wrapper class directly in your code by calling the class programmatically.

To use the user code directly, create an instance of the DAQmx user code class and call the appropriate function in your source code. You can create an instance of the user code directly in source code, just as you create an instance of any class directly in source code. Declare a variable of the appropriate type and use it directly. The .h

file for the user-friendly wrapper for the DAQmx task class contains additional information on using the user code.

Tip For more information on how to create user code, refer to the Using a DAQmx Task

Class in a Project topic in the NI Measurement Studio Help .

Creating an Instrument Control Application

To create a Measurement Studio instrument control application, use the

Instrument I/O Assistant. The Instrument I/O Assistant, as shown in

Figure 4-5, integrates into Visual Studio as a code designer. Use the Add

New Item wizard to add an instrumentation task to your project, and use the

Instrument I/O Assistant user interface to create and configure the instrumentation task. The Instrument I/O Assistant generates a Visual

Basic .NET, Visual C#, or Visual C++ class that includes the functionality you configure in the user interface. Use this assistant to help you write code that communicates with devices such as serial, Ethernet, or GPIB instruments.

Note The Instrument I/O Assistant is available only if you have installed either the

Measurement Studio Professional or Measurement Studio Enterprise package.




Refer to Chapter 5, the Walkthrough: Creating a Measurement Studio

Instrument I/O Application section, for step-by-step instructions on how to

use the Instrument I/O Assistant.

Figure 4-5. Instrument I/O Assistant

The Instrument I/O Assistant aids you in performing the following operations:

• Creating an instrumentation task class

• Configuring an instrumentation task class to communicate with an instrument and parse data you receive from the instrument

Tip For more information about using the Instrument I/O Assistant to create a

Measurement Studio instrument control application, refer to the Creating a Measurement

Studio Instrument Control Application section of the NI Measurement Studio Help .


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Selecting a Measurement Studio Parameter Value

To access I/O devices or resources, you must specify string constants or scalar values for many method parameters and property values. Use the

Measurement Studio Parameter Assistant, on the Measurement Studio menu, to discover and insert into your code valid parameter values for methods and various Measurement Studio class libraries, such as

NI-DAQmx, NI-488.2, and NI-VISA.

Note The Parameter Assistant is available in prior versions of Visual Studio only if you have at least one Measurement Studio class library installed that supports the Parameter

Assistant.

With the Parameter Assistant, you can select the correct parameter value for a device or resource, as shown in Figure 4-6, based on your current system configuration. Click the Insert Selected Item button on the Parameter

Assistant to insert the value into the current location in the active source file.

Figure 4-6. Measurement Studio Parameter Assistant

Tip For information about using the Measurement Studio Parameter Assistant to select a parameter value, refer to the Selecting a Measurement Studio Parameter Value section in the NI Measurement Studio Help .




Using the Instrument Driver Wizard

To use an IVI or VXI plug&play instrument driver with a C DLL in a

Measurement Studio .NET application, use the Measurement Studio .NET

Instrument Driver wizard to create .NET entry points to the C DLL functions you need to call from your application. Use the Add New Item wizard to select the .NET Instrument Driver Wizard.

The Measurement Studio .NET Instrument Driver wizard, as shown in

Figure 4-7, generates a .NET wrapper class for calling into IVI, VXI plug&play , and legacy instrument drivers based on the instrument driver function panel, header file, and an optional .sub

file for IVI drivers. The wizard can generate both Visual C# and Visual Basic .NET source code.

After completing the wizard, a new instrument driver wrapper class is added to your project and opened in the source code editor.

Figure 4-7. Launching the Measurement Studio .NET Instrument Driver Wizard from the Add New Item Wizard

Tip For information about the .NET instrument driver wizard, refer to the Using

Instrument Drivers in Measurement Studio Applications section in the NI Measurement

Studio Help .


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5

Getting Started with

Measurement Studio

The following sections include overview information and step-by-step instructions on developing applications with Measurement Studio tools and features. Refer to the Developing with Measurement Studio section and the

Getting Started with the Measurement Studio Class Libraries section of the

NI Measurement Studio Help for more information about the functionality of these tools and features.

Measurement Studio Walkthroughs

Use the following walkthroughs to help you develop Measurement Studio applications in Visual Studio 2005 or Visual Studio 2008:

•

Walkthrough: Creating a Measurement Studio Application with

Windows Forms Controls and Analysis

•

Walkthrough: Creating a Measurement Studio Application with Web

Forms Controls and Analysis

•

Walkthrough: Creating a Measurement Studio Application with

Windows Forms Controls and Network Variable

•

Walkthrough: Creating a Measurement Studio Application with Web

Forms Controls and Network Variable

•

Walkthrough: Creating a Measurement Studio NI-DAQmx

Application

•

Walkthrough: Creating a Measurement Studio Instrument I/O

Application



Chapter 5 Getting Started with Measurement Studio

Walkthrough: Creating a Measurement Studio

Application with Windows Forms Controls and Analysis

Note To complete this walkthrough, you must have either the Measurement Studio

Professional or Measurement Studio Enterprise package installed for Visual Studio 2005 or later. This walkthrough will not work with the Measurement Studio Standard package.

Measurement Studio includes user interface controls, such as a waveform graph control and a gauge control, and analysis functionality, such as signal generation and mathematical functions. This walkthrough is designed to help you learn how to add analysis and presentation functionality to a

Windows Forms application by taking you through the following steps:

• Setting up the project —Using the Measurement Studio Application

Wizard, you will create a new project that references the Measurement

Studio Analysis class library and Windows Forms controls.

• Adding user interface controls to the project —Using the Toolbox, smart tags, and the Properties window, you will add and configure a button, waveform graph, legend, gauge, and numeric edit user interface control.

• Generating, plotting, and analyzing the data —Using

NationalInstruments.Analysis.SignalGeneration.White

NoiseSignal and NationalInstruments.Analysis.Math.

Statistics.Mean

, you will generate data, plot the generated data on a waveform graph, and calculate the mean of the data.

• Customizing the user interface —Using smart tags and the Collection

Editor and Auto Format dialog boxes, you will display the mean value on the gauge and the numeric edit, as well as customize your user interface.

Before you begin

The following components are required to complete this walkthrough:

• Microsoft Visual Studio 2005 or Visual Studio 2008

• Measurement Studio 8.0.1 or later (Professional or Enterprise package) for Visual Studio 2005 or Measurement Studio 8.5 or later

(Professional or Enterprise package) for Visual Studio 2008


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Setting up the project

1.

Select Start»All Programs»Microsoft Visual Studio 2005»

Microsoft Visual Studio 2005 or Start»All Programs»Microsoft

Visual Studio 2008»Microsoft Visual Studio 2008 .

2.

Select File»New»Project . The New Project dialog box launches.

3.

In the Project Types pane, select Measurement Studio under Visual

C# or Visual Basic, depending on which language you want to create the project in.

4.

In the Templates pane, select NI Windows Application . Specify

MyMeasurementStudioProject for Name and specify a Location of your choice.

5.

Click OK . The Measurement Studio Application Wizard launches.

6.

Select Analysis Library and Windows Forms User Interface

Control Library .




Tip If you are working with an existing project, you can access the Add/Remove Class

Libraries dialog box by selecting Measurement Studio»View .NET Class Library

Wizard .

7.

Click Finish to display Form1 in the Windows Forms Designer.

Adding user interface controls to the project

1.

Select View»Toolbox to display the Toolbox. The Toolbox contains components and controls that you can add to your project.

2.

Expand the All Windows Forms group. The All Windows Forms group contains controls and components included in the

System.WindowsForms

namespace.

3.

Select the Button control and drag and drop it onto the form.

4.

Right-click the button and select Properties to display the Properties window. You configure the properties of the control in the Properties window.

5.

The Text property will be highlighted. Type Start for the button text.


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6.

Expand the Measurement Studio group in the Toolbox.

7.

Select the WaveformGraph control and drag and drop it onto the form.

8.

Right-click the waveform graph and select Edit Plots to display the WaveformPlot Collection Editor dialog box. You use the

WaveformPlot Collection Editor dialog box to add or remove plots and to configure plot properties.




Note You can also access the WaveformPlot Collection Editor dialog box by clicking the waveform graph smart tag. To access the smart tag, left click on the control to select it and then left click on the arrow button in the upper right corner of the control.

9.

Type Plot for the Name. Click OK .

10. Before you add the Measurement Studio legend, numeric edit, and gauge controls, you need to resize the form to accommodate them.

Select the form and use the double-sided arrow to resize it.

11. Select the Legend control and drag and drop it onto the form.

12. Select the NumericEdit control and drag and drop it onto the form.

13. Select the Gauge control and drag and drop it onto the form.

14. Click the gauge smart tag to display the Gauge Tasks.


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15. Type gauge for the name of the gauge.

The following screenshot shows Form1 with the user controls.




Generating, plotting, and analyzing the data

1.

Double-click the button control to display the Form1 code, with the cursor inside the click event handler of the button control.

2.

Add the following code to generate random data, plot the data, calculate the mean of the data, and display the mean on the gauge.

[VB.NET]

' Declare and initialize an instance of WhiteNoiseSignal.

Dim whiteNoise As New WhiteNoiseSignal()

' Store the generated data in a double array named data.

Dim data As Double() = whiteNoise.Generate(1000.0, 256)

' Use the PlotY method to plot the data.

Plot.PlotY(data)

' Use the Mean method to calculate the mean of the data.

Dim mean As Double = Statistics.Mean(data)

' Display the mean on the gauge.

gauge.Value = mean

[C#]

// Declare and initialize an instance of WhiteNoiseSignal.

WhiteNoiseSignal whiteNoise = new WhiteNoiseSignal();

// Store the generated data in a double array named data.

double[] data = whiteNoise.Generate(1000.0, 256);

// Use the PlotY method to plot the data.

Plot.PlotY(data);

// Use the Mean method to calculate the mean of the data.

double mean = Statistics.Mean(data);

// Display the mean on the gauge.

gauge.Value = mean;


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Customizing your user interface

1.

Right-click the legend and select Edit Items to display the LegendItem

Collection Editor dialog box. You use the LegendItem Collection

Editor dialog box to add or remove legend items and to configure legend item properties.

2.

Select Plot in the Source drop-down list and enter Signal in the Text box. Click OK . Now that you have specified a legend item for the plot, changes you make to the plot will be reflected on the legend.

3.

Right-click the graph and select Auto Format to display the Auto

Format dialog box. The Auto Format dialog box provides a set of pre-configured control styles. When you select a style and click OK , the Auto Format feature configures the appropriate control properties to reflect the style you chose.




4.

Select Points Only . Click OK . Notice that the legend changed automatically to match the formatting of the graph.


5.

Click the gauge smart tag to display the Gauge Tasks.

6.

Select Auto Format to display the Auto Format dialog box.

7.

Select Dark and click OK .

8.

Right-click the gauge and select Properties to display the Properties window.

9.

Set the Range property for the gauge with the drop-down Range type editor. Type -0.2

for the minimum value and type 0.2

for the maximum value.

10. Click the numeric edit smart tag to display the Numeric Edit Tasks.

11. Select Gauge in the Source drop-down list. Setting the Source property to the gauge allows two-way binding between the controls.

12. Deselect ArrowKeys , Buttons , and Text for the InteractionMode property of the numeric edit control. Deselecting these interaction modes makes the numeric edit an indicator. The numeric edit control only displays the calculated mean.

13. Select the Format Mode property and in the Numeric Edit Format

Mode Editor dialog box, change the Precision to 4 to show four decimal places of precision.

14. Select File»Save Form1.cs

to save your application.

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15. Select Debug»Start Without Debugging to run the application.

16. After your program builds, click Start . Notice the graph shows the data plot, and the gauge and the numeric edit display the mean of the data.


Application with Web Forms Controls and Analysis



Measurement Studio includes user interface controls, such as a waveform graph control and a gauge control, and Analysis functionality, such as signal generation and mathematical functions. This walkthrough is designed to help you learn how to add analysis and presentation functionality to a Web Forms application by taking you through the following steps:

• Setting up the project —Using the Measurement Studio Application

Wizard, you will create a new project that references the Measurement

Studio Analysis class library and Web Forms controls.

• Adding user interface controls to the project —Using the Toolbox and the Properties window, you will add and configure a button, waveform graph, legend, gauge, and numeric edit user interface control.




• Generating, plotting, and analyzing the data —Using

NationalInstruments.Analysis.SignalGeneration.White

NoiseSignal and NationalInstruments.Analysis.Math.

Statistics.Mean

, you will generate data, plot the generated data on a waveform graph, and calculate the mean of the data.

• Customizing the user interface —Using the Collection Editor and

Auto Format dialog boxes, you will display the mean value on the gauge and the numeric edit, as well as customize your user interface.







1.




2.

Select File»New»Web Site . The New Web Site dialog box launches.


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3.

In the Templates pane, select NI ASP.NET Web Site . Select File

System and specify a file path of your choice.

4.

Use the drop-down box to select Visual C# or Visual Basic , depending on which language you want to create the project in.

5.

Click OK . The Measurement Studio ASP.NET Web Site Wizard launches.

6.

Select Analysis Library and Web Forms User Interface Control

Library .





Libraries dialog box by selecting Measurement Studio»Add/Remove .NET Class

Libraries Wizard .

7.

Click Finish to display Default.aspx

in the Web Forms Designer.

8.

You can change the title of your Web page. Click inside the <title> tag and rename the title to Measurement Studio Web Forms

Controls and Analysis Walkthrough .


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Adding user interface controls to the project

In this section, you will build a Web page that looks like the following screenshot.

1.

Click Design in the lower left corner to switch from Source View to

Design View.

2.

Select View»Toolbox to display the Toolbox. The Toolbox contains components and controls that you can add to your project.

3.

Expand the HTML group on the Toolbox. Select the Table control in the Toolbox and drag and drop it on the form. You use the table cells to arrange the user interface controls on your Web page, as shown in the previous screenshot.

4.

The default table that appears is 3

×

3. This table provides a customizable form for arranging the user interface controls for your

Web page. Expand the table to approximately 300 px (pixels) tall by

550 px wide by clicking and dragging the table borders.

5.

If you are using Visual Studio 2005, merge the top two cells of all three columns by selecting the cells, right-clicking, and selecting Merge

Cells . If you are using Visual Studio 2008, merge the top two cells of all three columns by selecting the cells, right-clicking, and selecting

Modify»Merge Cells .

6.

Expand the Standard group on the Toolbox. The Standard group contains ASP.NET server controls included in the System.Web.UI

namespace.




7.

Select the Button control and drag and drop it into the lower right table cell.

8.

Right-click the button and select Properties to display the Properties window. You configure the properties of the control in the Properties window.

9.

Scroll to the Text property in the Properties window. Type Start for the button text.

10. Expand the Measurement Studio group on the Toolbox.

11. Select the WaveformGraph control and drag and drop it into the top table cell.

12. On the waveform graph smart tag, type graph for the name of the waveform graph ID.

Tip To access the smart tag, left click on a control to select it and then left click on the arrow button in the upper right corner of the control.


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13. Select the Legend control and drag and drop it into the bottom left table cell.

14. Select the NumericEdit control and drag and drop it into the bottom center table cell.

15. On the numeric edit smart tag, type numericedit for the name of the numeric edit ID.

16. Select the Gauge control and drag and drop it into the top table cell, to the right of the waveform graph. Resize controls and table cells as necessary.

17. On the gauge smart tag, type gauge for the name of the gauge ID.




The following screenshot shows Default.aspx

with the user controls.

Generating, plotting, and analyzing the data

1.

Double-click the button control to display the Default.aspx.cs

code, with the cursor inside the click event handler of the button control.

2.

Add the following code to generate random data, plot the data, calculate the mean of the data, and display the mean on the gauge.

[VB.NET]

' Declare and initialize an instance of WhiteNoiseSignal.

Dim whiteNoise As New WhiteNoiseSignal()

' Store the generated data in a double array named data.

Dim data As Double() = whiteNoise.Generate(1000.0, 256)

' Use the PlotY method to plot the data.

graph.PlotY(data)

' Use the Mean method to calculate the mean of the data.

Dim mean As Double = Statistics.Mean(data)

' Display the mean on the numeric edit.

numericedit.Value = mean

' Display the mean on the gauge.

gauge.Value = mean


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[C#]

// Declare and initialize an instance of WhiteNoiseSignal.

WhiteNoiseSignal whiteNoise = new WhiteNoiseSignal();

// Store the generated data in a double array named data.

double[] data = whiteNoise.Generate(1000.0, 256);

// Use the PlotY method to plot the data.

graph.PlotY(data);

// Use the Mean method to calculate the mean of the data.

double mean = Statistics.Mean(data);

// Display the mean on the numeric edit.

numericedit.Value = mean;

// Display the mean on the gauge.

gauge.Value = mean;

Customizing your user interface

1.

Select the Default.aspx

tab to return to the Web Forms Designer.

2.

Right-click the legend and select Edit Items to display the LegendItem

Collection Editor dialog box. You use the LegendItem Collection

Editor dialog box to add or remove legend items and to configure legend item properties.




3.

Select Plots[0] in the Source drop-down list and enter Signal in the

Text box. Click OK . Now that you have specified a legend item for the plot, changes you make to the plot will be reflected on the legend.

4.

Right-click the graph and select Auto Format to display the Auto

Format dialog box. The Auto Format dialog box provides a set of pre-configured control styles. When you select a style and click OK , the Auto Format feature configures the appropriate control properties to reflect the style you chose.

5.

Select Points Only . Click OK . Notice that the legend changed automatically to match the formatting of the graph.


6.

Right-click the gauge and select Auto Format to display the Auto

Format dialog box.

7.

Select Dark and click OK .

8.

On the gauge smart tag, set the Range property for the gauge with the drop-down Range type editor. Type -0.2

for the minimum value and type 0.2

for the maximum value.

9.

On the numeric edit smart tag, select Indicator for the

InteractionMode property of the numeric edit control.

10. On the numeric edit smart tag, select Format Mode and in the Numeric

Format Mode Editor dialog box, change the Precision to 4 to show four decimal places of precision. Click OK .

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11. Select File»Save Default.aspx


12. Select Debug»Start Without Debugging to run the application.

13. After your program builds, click Start . Notice the graph shows the data plot, and the gauge and the numeric edit display the mean of the data. The following screenshot shows Default.aspx

in its final form.





Application with Windows Forms Controls and

Network Variable



Measurement Studio includes user interface controls, such as a waveform graph control, and network variable functionality to transfer live measurement data between applications over the network. This walkthrough is designed to help you learn how to add network variable functionality to a Windows Forms application by taking you through the following steps:

• Writing an array of data to the server —Using

NationalInstruments.NetworkVariable.NetworkVariable

BufferedWriter<TValue> , you will create and run a console application that writes an array of values to the server.

• Setting up a Windows Forms project —Using the Measurement

Studio Application Wizard, you will create a new project that references the Measurement Studio Network Variable class library and

Windows Forms controls.

• Configuring the network variable data source control —Using the

Toolbox and the NationalInstruments.NetworkVariable.

WindowsForms.NetworkVariableDataSource

smart tag, you will add and configure a data source control to your application.

• Displaying the array of data on a Windows Forms page —Using the

Toolbox, you will add and configure a NationalInstruments.

WaveformGraph control to display the data.







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Writing an array of data to the server

1.




2.


3.

In the Project Types pane, select Visual C# or Visual Basic , depending on which language you want to create the project in.

4.

In the Templates pane, select Console Application . Specify

NetworkVariableWriter for Name and specify a Location of your choice.

5.

Click OK .

6.

Select Measurement Studio»Add/Remove .NET Class Libraries .

The Measurement Studio Add/Remove Class Libraries Wizard launches. You use this wizard to add Measurement Studio components to your project.




7.

Select NetworkVariable Communication Library . Click Finish .

8.

In Program.cs

, add the following code to write an array of data to the server:

Note You should choose the appropriate code depending on whether you created a VB or

C# project.

[VB.NET]

Imports System

Imports System.Collections.Generic

Imports System.Text

Imports System.Threading

Imports NationalInstruments.NetworkVariable

Module Module1

Private Function GenerateDoubleArray(ByVal phase As Double) As Double()

Dim values(999) As Double

Dim x As Integer

For x = 0 To 999 values(x) = Math.Sin(((2 * Math.PI * x) / 1000) + phase) * 2

Next x


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Return values

End Function

Sub Main()

Const location As String = "\\localhost\system\double"

Dim bufferedWriter As NetworkVariableBufferedWriter(Of Double()) =

New

NetworkVariableBufferedWriter(Of Double())(location) bufferedWriter.Connect()

Dim phase As Integer = 0

While (True)

Dim values As Double() = GenerateDoubleArray(phase)

Console.WriteLine("Writing Array") bufferedWriter.WriteValue(values)

Thread.Sleep(500) phase = phase + 1

End While

End Sub

End Module

[C#] using System; using System.Collections.Generic; using System.Text; using System.Threading; using NationalInstruments.NetworkVariable; namespace NetworkVariableWriter

{ class Program

{

private static double[] GenerateDoubleArray(double phase)

{

double[] values = new double[1000];

for (int x = 0; x < 1000; x++)

values[x] = Math.Sin(((2 * Math.PI * x) / 1000) + phase) * 2;

return values;

}

static void Main(string[] args)

{

const string Location = @"\\localhost\system\double";

NetworkVariableBufferedWriter<double[]> bufferedWrite = new

NetworkVariableBufferedWriter<double[]>(Location);

bufferedWrite.Connect();

int phase = 0;

while (true)

{

double[] value = GenerateDoubleArray(phase);

Console.WriteLine("Writing array");




}

bufferedWrite.WriteValue(value);

Thread.Sleep(500);

phase++;

}

}

}

9.

Select Debug»Start Without Debugging to run the application.

10. Minimize the console, but keep the application running.


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Setting up a Windows Forms project

1.


Microsoft Visual Studio 2005 .

2.


3.

In the Project types pane, select Measurement Studio under Visual

C# or Visual Basic , depending on which language you want to create the project in.

4.

In the Templates pane, select NI Windows Application . Name the project WindowsNetworkVariableReader and specify a Location you wish to save to project by clicking Browse and navigating to a directory of your choice.

5.

Click OK . The Measurement Studio Application Wizard launches.




6.

Select Network Variable Communication Library and Windows

Forms User Interface Control Library .


Libraries dialog box by selecting Measurement Studio»Add/Remove Class Libraries

Wizard .

7.

Click Finish to display Form1 in the Windows Forms Designer.


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Configuring the network variable data source control

1.

Select View»Toolbox to display the Toolbox. The toolbox contains components and controls that you can add to your project.

2.

Expand the Measurement Studio group on the Toolbox.

3.

Select the NetworkVariableDataSource control in the toolbox and drag and drop it on the form. The NetworkVariableDataSource control is a data source control with functionality similar to System.Web.

UI.WebControls.ObjectDataSource

and System.Web.UI.

WebControls.SqlDataSource in the .NET Framework. The

NetworkVariableDataSource control encapsulates Network Variable functionality.

4.

In the NetworkVariableDataSource smart tag, select Edit Bindings to launch the NetworkVariableBinding Collection Editor dialog box.

5.

Select Add to create a connection with the underlying network variable, You can use the NetworkVariableBinding Collection Editor to configure the binding properties. Enter 0 as the DefaultReadValue .




6.

For the Location , browse to the \\localhost\System\double location in the Select Network Item dialog box.

7.

Click OK to return to the NetworkVariableBinding Collection Editor dialog box.

8.

After you configure the binding properties, click OK to return to the

Windows Forms Designer.

Displaying the array of data on a Windows form

1.

Select WaveformGraph in the Toolbox and drag and drop it on the form.

2.

Right-click the waveform graph and select Properties to display the

Properties window for the graph. You can configure the properties of the control in the Properties window.

3.

Expand the Data Bindings group in the Properties window.

Select Other Data Sources»Form 1 List Instances» networkVariableDataSource1»Binding1 from the Binding Data drop-down list. This will bind the waveform graph to the network variable that you are writing to in the console application. The waveform graph will then read and display the data being written to the network variable.

4.

Select File»Save Form1 to save your application.

5.

Select Debug»Start Without Debugging to run the application. The waveform graph displays the array of data.


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Application with Web Forms Controls and Network

Variable



Measurement Studio includes user interface controls, such as a waveform graph control, and network variable functionality to transfer live measurement data between applications over the network. This walkthrough is designed to help you learn how to add network variable functionality to a Web Forms application by taking you through the following steps:

• Writing an array of data to the server —Using

NationalInstruments.NetworkVariable.NetworkVariable

BufferedWriter<TValue> , you will create and run a console application that writes an array of values to the server.

• Setting up a Web Forms project —Using the Measurement Studio

Application Wizard, you will create a new project that references the

Measurement Studio Network Variable class library and Web Forms controls.

• Configuring the network variable data source control —Using the

Toolbox and the NationalInstruments.NetworkVariable.

WebForms.NetworkVariableDataSource

smart tag, you will add and configure a data source control to your application.




• Displaying the array of data on a Web page —Using the Toolbox, you will add and configure an NationalInstruments.UI.

WebForms.AutoRefresh

control and a NationalInstruments.

UI.WebForms.WaveformGraph

control to display the data.






Writing an array of data to the server

1.




2.

Select File»New»Project . The New Project dialog launches.


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3.

In the Project Types pane, select Visual C# or Visual Basic , depending on which language you want to create the project in.

4.

In the Templates pane, select Console Application . Specify

NetworkVariableWriter for Name and specify a Location of your choice.

5.

Click OK .

6.

Select Measurement Studio»Add/Remove .NET Class Libraries .

The Measurement Studio Add/Remove Class Libraries wizard launches. You use this wizard to add Measurement Studio components to your project.

7.

Select NetworkVariable Communication Library . Click Finish .




8.

In Program.cs

, add the following code to write an array of data to the server:

[VB.NET]

Imports NationalInstruments.NetworkVariable

Imports System.Threading

Imports System

Module Module1

Private Function GenerateDoubleArray(ByVal phase As Double) As Double()

Dim values(999) As Double

Dim x As Integer

For x = 0 To 999

values(x) = Math.Sin(((2 * Math.PI * x) / 1000) + phase) * 2

Next x

Return values

End Function

Sub Main()

Const location As String = "\\localhost\system\double"

Dim bufferedWriter As NetworkVariableBufferedWriter(Of Double()) =

New NetworkVariableBufferedWriter(Of Double())(location)

bufferedWriter.Connect()

Dim phase As Integer = 0

While (True)

Dim values As Double() = GenerateDoubleArray(phase)

Console.WriteLine("Writing Array")

bufferedWriter.WriteValue(values)

Thread.Sleep(500)

phase = phase + 1

End While

End Sub

End Module

[C#] using System; using System.Threading; using NationalInstruments.NetworkVariable; namespace NetworkVariableWriter

{ class Program

{

private static double[] GenerateDoubleArray(double phase)

{

double[] values = new double[1000];

for (int x = 0; x < 1000; x++)

values[x] = Math.Sin(((2 * Math.PI * x) / 1000) + phase) * 2;

return values;


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}

static void Main(string[] args)

{

const string Location = @"\\localhost\system\double";

NetworkVariableBufferedWriter<double[]> bufferedWriter = new

NetworkVariableBufferedWriter<double[]>(Location);

bufferedWriter.Connect();

int phase = 0;

while (true)

{

double[] value = GenerateDoubleArray(phase);

Console.WriteLine("Writing array");

bufferedWriter.WriteValue(value);

Thread.Sleep(500);

phase++;

}

}

}

}

9.

Select Debug»Start Without Debugging to run the application.

10. Minimize the console application, but keep the application running.




Setting up a Web Forms project

1.




2.

Select File»New»Web Site . The New Web Site dialog box launches.

3.

In the Templates pane, select NI ASP.NET Web Site . Select File

System for Location and specify a file path of your choice.

4.

Use the drop-down box to select Visual C# or Visual Basic , depending on which language you want to create the project in.

5.

Click OK . The Measurement Studio ASP.NET Web Site Wizard launches.


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6.

Select Network Variable Communication Library and Web Forms

User Interface Control Library .


Libraries dialog box by selecting Measurement Studio»Add/Remove Class Libraries

Wizard .

7.

Click Finish to display Default.aspx

in the Web Forms Designer.

8.

You can rename the title of your Web page. Click inside the <title> tag and rename the title to Measurement Studio Network Variable and Web Forms Controls Walkthrough .




Configuring the network variable data source control

1.

Click Design in the lower left corner to switch from Source View to

Design View.

2.

Select View»Toolbox to display the Toolbox. The toolbox contains components and controls that you can add to your project.

3.

Expand the Measurement Studio group on the Toolbox.

4.

Select the NetworkVariableDataSource control in the toolbox and drag and drop it on the form. The NetworkVariableDataSource control is a data source control with functionality similar to System.Web.UI.

WebControls.ObjectDataSource

and System.Web.UI.

WebControls.SqlDataSource in the .NET Framework. The

NetworkVariableDataSource control encapsulates Network Variable functionality.

5.

In the NetworkVariableDataSource smart tag, select Edit Bindings to launch the NetworkVariableBinding Collection Editor dialog box.


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6.

Select Add . You add a binding to create a connection with the underlying network variable, and you use the NetworkVariableBinding

Collection Editor to configure the binding properties. Select Object for the BindingType. You select Object because this walkthrough binds to NationalInstruments.UI.WebForms.

WaveformGraph.BindingData

. Enter 0 as the DefaultReadValue .

7.

Browse to the \\localhost\System\double location in the Select

Network Item dialog box.




8.

Click OK to return to the NetworkVariableBinding Collection Editor dialog box.

9.

After you configure the binding properties, click OK to return to the

ASP.NET Designer.

Displaying the array of data on a Web page

1.

Select WaveformGraph in the Toolbox and drag and drop it on the form.

2.

Select AutoRefresh in the Toolbox and drag and drop it on the form.

3.

In the AutoRefresh smart tag, check Enabled . Select Edit Default

Refresh Items to launch the RefreshItem Collection Editor dialog box.


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4.

Select Add . Select WaveformGraph1 for the ItemID and click OK .

5.

Double-click the AutoRefresh control. Add the following code to the

AutoRefresh event handler to bind the waveform graph control to the network variable data source control:

[VB.NET]

WaveformGraph1.BindingData =

NetworkVariableDataSource1.Bindings(0).GetValue()

[C#]

WaveformGraph1.BindingData =

NetworkVariableDataSource1.Bindings[0].GetValue();




6.

Select File»Save Default.aspx


7.

Select Debug»Start Without Debugging to run the application. The waveform graph displays the array of data.

Note You can also use the System.Web.UI.WebControls.FormView

control to bind to NationalInstruments.NetworkVariable.WebForms.

NetworkVariableDataSource . Refer to Using the Measurement Studio Network

Variable Data Source in Web Forms for more information.


NI-DAQmx Application


Professional or Measurement Studio Enterprise package installed. This walkthrough requires the DAQ Assistant, which is not included in the Measurement Studio Standard package.

This walkthrough is designed to help you learn how to create an

NI-DAQmx applicationby taking you through the following steps:

• Setting up the project —Using the Measurement Studio DAQ

Application Wizard, you will create a new project that references the

NI-DAQmx assembly and launches the DAQ Assistant to create an

NI-DAQmx task.


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• Configuring your task —Using the DAQ Assistant, you will interactively configure and save your task. The wizard then generates code to reflect your configuration settings. The wizard also generates a component that provides common operations for your task and integration with the Windows Forms designer.

• Creating a custom user interface for the task —Using the DAQ

Component UI generation wizard, you will create a custom user interface that uses the DAQ component you created to automatically plot the DAQ signal.



• Visual Studio 2005 or Visual Studio 2008



• NI-DAQmx 8.1 or later for Visual Studio 2005 or NI-DAQmx 8.7.1 or later for Visual Studio 2008

• NI-DAQmx-supported DAQ device or simulated device

For information about installing and configuring your DAQ device, refer to the DAQ Getting Started Guide . You can also use a simulated device to complete this walkthrough. For information on how to create an

NI-DAQmx simulated device, refer to Creating NI-DAQmx Simulated

Devices in the Measurement & Automation Explorer Help for NI-DAQmx .

To open this help, select Start»All Programs»National Instruments»

Measurement & Automation . In Measurement & Automation Explorer

(MAX), select Help»Help Topics»NI-DAQmx»MAX Help for

NI-DAQmx . For the purposes of this walkthrough, the NI PCI-6280 device of the M Series DAQ family is recommended.

To set up the project

1.

Open Visual Studio from Start»All Programs»Microsoft Visual

Studio 2005»Microsoft Visual Studio 2005 or Start»All Programs»

Microsoft Visual Studio 2008»Microsoft Visual Studio 2008 .

2.

Select File»New»Project .The New Project dialog box launches.




3.

In the Project types pane, expand the Visual C# or Visual Basic node, depending on which language you want to create the project in, and select Measurement Studio . Code generation works in both languages.

4.

In the Templates pane, select NI DAQ Windows Application . Specify

MyDAQmxProject for Name and specify a Location of your choice.

Click OK . The Measurement Studio DAQ Application Wizard launches.


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5.

In the Add DAQ Component dialog box, you can choose to create a new project task, create a new MAX task, create a reference to a MAX task, copy a MAX task to a project task, or copy an existing .mxb

. For this walkthrough, select Create a new project task and click Finish .

The Measurement Studio DAQ Application Wizard automatically sets up your data acquisition project and launches the DAQ Assistant.




To configure your task

1.

In the Create New dialog box of the DAQ Assistant, you can begin to interactively define your DAQ task. Select Acquire Signals , and then

Analog Input as the measurement type for your task.

2.

Next, select Voltage .


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3.

From the Supported Physical Channels tree in the Physical tab, select the physical channel, such as ai1 , on the DAQ device to which you connected the voltage signal. Click Finish .

Note You can also use a simulated device in this walkthrough. For more information, refer to Creating NI-DAQmx Simulated Devices in the Measurement & Automation Explorer

Help for NI-DAQmx .




4.

In the Edit DAQ Task dialog box, you can edit the configuration of your DAQ task. If the embedded DAQ Assistant help is not open by default, click the Show Help button in the upper-right corner of the window to display the help.


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5.

To complete the DAQ configuration, select the N Samples Acquisition

Mode in the Timing Settings section. For more information on timing, refer to Timing in the NI-DAQmx Help .

6.

Next, click the Run button in the toolbar near the top of the Edit DAQ

Task dialog box. The test runs automatically. You can run the test in the

DAQ Assistant to test the task and make sure you connected the signal properly. If necessary, you can modify the settings before any code is generated.

7.

Click the Finish button in the Edit DAQ Task dialog box to complete the configuration of your DAQ task and to launch the Configure DAQ

Component UI wizard.




To create a custom user interface for the task

1.

In the Configure DAQ Component UI wizard, you can customize and preview a user interface and code for your task.

2.

Click Finish to generate the task user interface in your project form.


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The wizard also generates event handlers and code to acquire data and present it on your generated user interface.




3.

Press <F5> to run the application.

4.

After you have started the application, click the Read button to begin acquiring data from your DAQ device.

What’s next

To learn more about tasks, channels, and other NI-DAQmx concepts, refer to the NI-DAQmx Help located at Start»All Programs»National

Instruments»NI-DAQ»NI-DAQmx Help .

For more information about creating and using tasks in Measurement

Studio, refer to Using the Measurement Studio NI-DAQmx .NET Library.

You can also look at examples that ship with NI-DAQmx. Refer to

Measurement Studio NI-DAQmx .NET Examples for the locations of these examples.


Instrument I/O Application


Professional or Measurement Studio Enterprise package installed. This walkthrough requires the Instrument I/O Assistant, which is not included in the Measurement Studio

Standard package.


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The National Instruments Instrument I/O Assistant organizes instrument communication for a serial, Ethernet, or GPIB instrument into ordered steps. This walkthrough is designed to help you learn how to build an instrument I/O application by taking you through the following steps:

• Setting up the project —Using the Measurement Studio VISA

Windows Application project, you will create a new project that references the VisaNS assembly and launches the Instrument I/O

Assistant to create a VisaNS task.

• Performing a query on the instrument —Using the Instrument I/O

Assistant, you will write a command to an instrument and read the instrument response.

• Displaying Instrument I/O Assistant data on your UI —Using text box and button controls, you will create a Windows Forms application to display the Instrument I/O Assistant data.



• Visual Studio 2005 or Visual Studio 2008



• National Instruments Device Driver CD

• Message-based instrument on a supported VISA bus, such as GPIB or

Serial

Note For more information about the Instrument I/O Assistant, refer to the Instrument I/O

Assistant Help by selecting the Show Help button inside the assistant.


1.

Open Visual Studio from Start»All Programs»Microsoft Visual

Studio 2005»Microsoft Visual Studio 2005 or Start»All Programs»

Microsoft Visual Studio 2008»Microsoft Visual Studio 2008 .

2.






3.

In the Project Types pane, select Measurement Studio under Visual

C# or Visual Basic, depending on which language you want to create the project in. This walkthrough refers to Visual C#, but you can follow the same process if you use Visual Basic .NET.

4.

In the Templates pane, select NI VISA Windows Application .

Specify MyIIOAProject for Name and select a Location of your choice.

5.

Click OK . Your project opens in Visual Studio with a VisaTask.mxb

file and references to NationalInstruments.VisaNS

,

NationalInstruments.UI.WindowsForms

, and

NationalInstruments created for you.

6.

Select View»Solution Explorer to display the Solution Explorer.

Double-click VisaTask.mxb

in the Solution Explorer to launch the

Instrument I/O Assistant.

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Performing a query on the instrument

Note This walkthrough was created using the NI Instrument Simulator. Any identification information or sample code generated for this device will be different depending on the instrument actually used.

1.

The Select Instrument step automatically appears in the Step

Sequence window when you launch the Instrument I/O Assistant.

Select the instrument you want to communicate with or the port to which your instrument is connected from the Select an instrument drop-down listbox.

2.

Select Add Step and then select Query and Parse from the expanded list. You use a Query and Parse step to both write a command to an instrument and read the instrument’s response.

3.

Enter the command *idn?

and click Run this step . The *idn?

command is a standard instrument command for querying an instrument’s identification information. If your instrument does not support the *idn?

command, refer to the documentation for the instrument for more information about the instrument’s command set.

4.

Click Auto parse to parse the instrument’s response. The Auto parse button automatically parses binary block data and ASCII text. Refer to the Parsing an Instrument Response topic in the Instrument I/O

Assistant Help for information about how the Assistant parses different data formats.




5.

If there are more than two tokens in the token list, remove them for this example. To remove a token, right-click on it in the response window and select Remove . The response window displays data in binary form, ASCII form, or binary form and ASCII form together. If there is only one token in the token list, split the token into two tokens for this example. Refer to Parsing an Instrument Response in the Instrument

I/O Assistant Help for more information about how to manually parse the data into two tokens.

6.

In the Token name text box, enter Vendor to rename the first token.

You use this name to reference the token in your application. Ensure that the data type of the token is String . You specify the data type of the token using the Type drop-down list on the Data Type tab.


7.

Select Token2 , rename it to Device , and ensure that the data type for

Token2 is String . To select Token2, left click on it within the Query and Parse step in the Step Sequence window on the left side of the

Instrument I/O Assistant. Follow the instructions from step 6 to change the token name and to set the token data type.

8.

Select File»Save to save your task.

9.

Select View»Solution Explorer to display the Solution Explorer.

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10. Click the Show All Files icon and expand the VisaTask.mxb

node.

11. Double-click the VisaNSTask1 file to view the code that the

Instrument I/O Assistant generated for you.

Displaying Instrument I/O Assistant data on your user interface

1.

Double-click the Form1 file in the Solution Explorer to open your main application form.

2.

Select View»Toolbox to display the Toolbox.

3.

Expand the All Windows Forms group on the Toolbox.

4.

Select the Button control and drag and drop it onto the form.

5.

Select the TextBox control and drag and drop it onto the form. Repeat this step to add a second text box to the form. The following screenshot shows the controls on the form:

6.

Double-click the Button control to display the Form1 code, with the cursor inside the click event handler of the button control.




7.

Add the following code to display the vendor and model name of your instrument in the text boxes.

[VB.NET]

' Declare an instance of VisaTask

Dim myTask As New VisaTask()

Dim results As VisaTaskResults

'Display the data in the text boxes results = myTask.Run() textBox1.Text = results.Vendor

textBox2.Text = results.Device

[C#]

//Declare an instance of VisaTask

VisaTask myTask = new VisaTask();

//Display the data in the text boxes

VisaTaskResults results = myTask.Run(); textBox1.Text = results.Vendor; textBox2.Text = results.Device;

Note Your sample code will be different depending on the instrument actually used.

8.

Build and run the application.

9.

Click the Button on the form to run the task. The following screenshot shows the controls on the form, with sample returned data.

Note Although this walkthrough only covers the use of a simple Query and Parse step, the Instrument I/O Assistant offers additional capabilities, such as independent Write and

Read and Parse steps and advanced parsing capabilities. The following screenshot shows the IIOA’s ability to scale and parse IEEE long definite block data.


5-58 ni.com

A

Technical Support and

Professional Services

Visit the following sections of the award-winning National Instruments

Web site at ni.com

for technical support and professional services:

• Support —Technical support resources at ni.com/support include the following:

– Self-Help Technical Resources —For answers and solutions, visit ni.com/support for software drivers and updates, a searchable KnowledgeBase, product manuals, step-by-step troubleshooting wizards, thousands of example programs, tutorials, application notes, instrument drivers, and so on.

Registered users also receive access to the NI Discussion Forums at ni.com/forums . NI Applications Engineers make sure every question submitted online receives an answer.

– Standard Service Program Membership —This program entitles members to direct access to NI Applications Engineers via phone and email for one-to-one technical support as well as exclusive access to on demand training modules via the Services

Resource Center. NI offers complementary membership for a full year after purchase, after which you may renew to continue your benefits.

For information about other technical support options in your area, visit ni.com/services , or contact your local office at ni.com/contact .

• Training and Certification —Visit ni.com/training for self-paced training, eLearning virtual classrooms, interactive CDs, and Certification program information. You also can register for instructor-led, hands-on courses at locations around the world.

• System Integration —If you have time constraints, limited in-house technical resources, or other project challenges, National Instruments

Alliance Partner members can help. To learn more, call your local

NI office or visit ni.com/alliance .

© National Instruments Corporation A-1


Appendix A Technical Support and Professional Services

If you searched ni.com

and could not find the answers you need, contact your local office or NI corporate headquarters. Phone numbers for our worldwide offices are listed at the front of this manual. You also can visit the Worldwide Offices section of ni.com/niglobal to access the branch office Web sites, which provide up-to-date contact information, support phone numbers, email addresses, and current events.


A-2 ni.com

Glossary

A

ActiveX

ActiveX control analog I/O annotate

ANSI C

API array control assembly

ActiveX control container asynchronous

Set of Microsoft technologies for reusable software components. Formerly called OLE.

Reusable software component that adds functionality to any ActiveX control container through exposed properties, methods, and events. The

Measurement Studio data acquisition, user interface, and analysis controls are examples of ActiveX controls.

Development environment that fully supports ActiveX controls and integrates them into its own environment using COM. An ActiveX control container enables you to specify how ActiveX controls interact with the environment through environment properties. Visual Basic is an example of an ActiveX control container.

Reading or writing data in continuously variable physical quantities, such as voltage or current.

Adding text, arrows, or shapes to describe or highlight a point or region on a graph.

C programming language defined by the American National Standards

Institute.

Application Programming Interface. A specification of software functions and their input and return parameters.

An array of Measurement Studio user interface controls that behave as a single unit.

A collection of one or more files that are versioned and deployed as a unit.

An assembly is the primary building block of a .NET Framework application. All managed types and resources are contained within an assembly and are marked either as accessible only within the assembly or as accessible from code in other assemblies.

Function that begins an operation and returns control to the program prior to the completion or termination of the operation.

© National Instruments Corporation G-1


Glossary

B

button

C

channel chart client callback

CodeBuilder

A control used to input or display Boolean information or to initiate an action in a program.

1. Physical—a terminal or pin at which you can measure or generate an analog or digital signal. A single physical channel can include more than one terminal, as in the case of a differential analog input channel or a digital port of eight lines. The name used for a counter physical channel is an exception because that physical channel name is not the name of the terminal where the counter measures or generates the digital signal.

2. Virtual—a collection of property settings that can include a name, a physical channel, input terminal connections, the type of measurement or generation, and scaling information. You can define NI-DAQmx virtual channels outside a task (global) or inside a task (local). Configuring virtual channels is optional in Traditional NI-DAQ and earlier versions, but is integral to every measurement you take in NI-DAQmx. In Traditional

NI-DAQ, you configure virtual channels in MAX. In NI-DAQmx, you can configure virtual channels in either MAX or in a program, and you can configure channels as part of a task or separately.

3. Switch—a switch channel represents any connection point on a switch.

It may be made up of one or more signal wires (commonly one, two, or four), depending on the switch topology. A virtual channel cannot be created with a switch channel. Switch channels may be used only in the

NI-DAQmx Switch functions and VIs.

To append new data points to the end of an existing plot over time.

In Web Forms, page calls back to the server without fully posting back.

Callbacks are asynchronous and are accomplished with XML-HTTP.

Client callbacks do not include postback data, and they do not force the page to refresh. Client callbacks do require a browser that supports the

XML-HTTP protocol.

LabWindows/CVI feature that creates code based on a .uir

file to connect your GUI to the rest of your program. This code can be compiled and run as soon as it is created.


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Glossary coercion

COM complex graph context-sensitive help control counter/timer I/O cursor cursor label

Automatic conversion that Measurement Studio controls perform to change the numeric representation of a data element.

Component Object Model. Microsoft specification for architecting and developing reusable software components.

A control that displays a ComplexDouble data type; the ComplexDouble data type represents a complex number of type Double that is composed of a real part and an imaginary part.

Help for dialog boxes, the controls in dialog boxes, and keywords in source code that you can access with the key or a Help button, or by clicking the link that appears in the Dynamic Help window in Visual Studio.

1. ActiveX control. See

ActiveX control

.

2. Object for entering, displaying, or manipulating data on a user interface.

Reading or writing data based on high-precision timing through a counter or timer. By combining a counter with a highly accurate clock, you can create a wide variety of timing and counting applications, such as monitoring and analyzing digital waveforms and generating complex square waves.

Flashing rectangle that shows where you may enter text on the screen. If you have a mouse installed, there is a rectangular mouse cursor, or pointer.

Text object used to display X and Y coordinates that a cursor crosshair points to on a graph.

D

DAQ

DAQ Assistant

DAQ device

Data acquisition. Process of acquiring data, typically from A/D or digital input plug-in boards.

A graphical interface for configuring measurement tasks, channels, and scales.

A device that acquires or generates data and can contain multiple channels and conversion devices. DAQ devices include plug-in devices, PCMCIA cards, and DAQPad devices, which connect to a computer USB or 1394

(FireWire

®

) port. SCXI modules are considered DAQ devices.



Glossary

DataSocket device digital I/O digital waveform graph distribution

DLL

DMM downlevel browser driver

DSTP

Technology that simplifies live data exchange between applications and

HTTP, FTP, OPC, logos (Lookout objects) and file servers over the Internet.

It provides one common API to a number of different communication protocols.

An instrument or controller you can access as a single entity that controls or monitors real-world I/O points. A device is often connected to a host computer through some type of communication network. See also

DAQ device and

measurement device .

Reading or writing digital representations of data in discrete units (the binary digits 1 and 0). Digital information is either on or off.

A control that displays DigitalWaveform data on a Windows Forms or

Web Forms user interface; the DigitalWaveform data type represents a set of digital states that are grouped by samples or signals.

Ability to install programs you develop with Measurement Studio to others working on different computers.

Dynamic Link Library. A library of functions that link to a program and load at run time rather than being compiled into the program. Loading libraries only when they are needed saves memory in software applications.

Digital Multimeter. A common measurement instrument that measures resistance, current, and voltage in a wide variety of applications.

Previous generation Web browser with limited client interaction. See also

uplevel browser .

Software that controls a specific hardware device, such as a data acquisition board or GPIB interface board. See also

instrument driver

.

DataSocket Transfer Protocol. Protocol based on TCP/IP to exchange data directly between two applications using DataSocket clients. Data is passed through a DataSocket Server between the applications.


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E

Ethernet event

FTP

G

gauge

GPIB executable

F

form front panel graph

H

HTTP

Glossary

Standard connection type for networks, where computers are connected by coaxial or twisted-pair cable.

Object-generated response to some action or change in state, such as a mouse click or a completed acquisition. The event calls an event procedure that processes the event.

Program file with a .exe

extension that you can run independently of the development environment in which it was created.

Window or area on the screen on which you place controls and indicators to create the user interface for your program.

Interactive user interface of a virtual instrument. Modeled after the front panel of physical instruments, it is composed of switches, slides, meters, graphs, charts, gauges, LEDs, and other controls and indicators.

File Transfer Protocol. Protocol based on TCP/IP to exchange files between computers.

A control used to input or display numerical data.

General Purpose Interface Bus. The standard bus used for controlling electronic instruments with a computer. Also called IEEE 488 bus because it is defined by ANSI/IEEE Standards 488-1978, 488.1-1987, and

488.2-1987.

A 2D or 3D display of one or more plots.

HyperText Transfer Protocol. Protocol based on TCP/IP, which is used to download Web pages from an HTTP server to a Web browser.



I

Glossary

IEEE 488

IMAQ Vision indicator installer instrument driver

Instrument I/O

Assistant interface

IVI

Shortened notation for ANSI/IEEE Standards 488-1978, 488.1-1987, and

488.2-1987. See also

GPIB

.

National Instruments image acquisition and analysis software that you can use to acquire images from National Instruments image acquisition

(IMAQ) boards, display them in your program, perform interactive viewer operations, and analyze the images to extract information.

A control in read-only mode.

Software program that copies program, system, and other necessary files to computers.

Library of functions to control and use one specific physical instrument.

Also a set of functions that adds specific functionality to an application.

Assists in writing code to communicate with devices such as serial,

Ethernet, or GPIB instruments. The Instrument I/O Assistant provides a user interface within the Visual Studio environment. You use the

Instrument I/O Assistant to interactively write commands to a device, read data that the device returns, and specify how to parse the response.

Connection between one or more of the following: hardware, software, and the user. For example, hardware interfaces connect two other pieces of hardware.

Interchangeable Virtual Instruments. A technology involving standard programming interfaces for classes of instruments, such as oscilloscopes,

DMMs, and function generators, that results in hardware-independent instrument drivers. The IVI standard programming interfaces have been defined by the IVI Foundation, an industry consortium. Refer to www.ivifoundation.org

for more information.

K

knob A control used to input or display numerical data.


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Glossary

L

LabVIEW

LabWindows/CVI

LED legend

Laboratory Virtual Instrument Engineering Workbench. Graphical development environment used for developing test and measurement applications.

ANSI C development environment for building test and measurement applications.

Light-Emitting Diode. An indicator that emits a light when current passes through it. For example, an LED shows if your computer or printer is turned on.

A control that displays symbols and descriptions for a specific set of elements of another object, such as the plots or cursors of a graph.

M

matrix

MB

Measurement &

Automation Explorer

(MAX) measurement device

Measurement Studio meter method

MFC

A rectangular array of numbers or mathematical elements that represent the coefficients in a system of linear equations.

Megabytes of memory.

National Instruments tool for configuring your National Instruments hardware and driver software; executing system diagnostics; adding new devices, interfaces, and virtual channels; and viewing devices and instruments connected to your system.

DAQ devices such as the E Series multifunction I/O (MIO) devices, SCXI signal conditioning modules, and switch modules.

National Instruments software that includes tools to build measurement applications in Visual Basic .NET, Visual C#, and Visual C++.


Function that performs a specific action on or with an object. The operation of the method often depends on the values of the object properties.

Microsoft Foundation Class. A framework for programming in Microsoft

Windows, MFC provides code for managing windows, menus, and dialog boxes; performing basic input/output; storing collections of data objects; and more.



Glossary

N

NI-488.2

NI-DAQ

NI-DAQmx

NI-IMAQ numeric edit

O

OCX

OLE

OPC oscilloscope

Driver-level software to control and communicate with National

Instruments GPIB hardware.

Driver-level software to control and communicate with DAQ hardware.

NI-DAQ is an extensive library of VIs and functions you can call from an application development environment (ADE) to program all the features of an NI measurement device, such as configuring, acquiring and generating data from, and sending data to the device.

The latest NI-DAQ driver with new VIs, functions, and development tools for controlling measurement devices. The advantages of NI-DAQmx over earlier versions of NI-DAQ include the DAQ Assistant for configuring channels and measurement tasks for your device for use in LabVIEW,

LabWindows/CVI, and Measurement Studio; increased performance such as faster single-point analog I/O; and a simpler API for creating DAQ applications using fewer functions and VIs than earlier versions of

NI-DAQ.

Driver-level software to control and communicate with National

Instruments image acquisition hardware.

A control used to display and edit numeric values.

OLE Control eXtension. Another name for ActiveX controls, reflected by the .ocx

file extension of ActiveX control files.

Object Linking and Embedding. See also

ActiveX .

OLE for Process Control. An industry standard based on ActiveX and

COM technologies that enables you to create a single client application that can communicate with disparate devices. Refer to www.opcfoundation.org


Measurement instrument widely used in high-speed testing applications, such as telecommunication physical layer testing, video testing, and high-speed digital design verification.


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Glossary

P

PCI

PID plot point postback property property editor property pages

PXI

Peripheral Component Interconnect. High-performance expansion bus architecture commonly found in PCs.

Proportional-Integral-Derivative. A three-term control mechanism combining proportional, integral, and derivative control. You might use a

PID algorithm to control processes such as heating and cooling systems, fluid level monitoring, flow control, and pressure control.

1. Trace (data line) on a graph representing the data in one row or column of an array.

2. To display a new set of data while deleting any previous data on the graph.

Structure that contains two 16-bit integers that represent horizontal and vertical coordinates.

The process in which a Web page sends data back to the same page on the server.

Attribute that defines the appearance or state of an object. The property can be a specific value or another object with its own properties and methods.

For example, a value property is the color (property) of a plot (object), while an object property is a specific Y axis (property) on a graph (object).

The Y axis itself is another object with properties, such as minimum and maximum values.

A control used to configure properties for Windows Forms controls at run time.

Window or dialog box that displays current configuration information and allows users to modify the configuration.

PCI eXtensions for Instrumentation. Rugged, open platform for modular instrumentation with specialized mechanical, electrical, and software features. Refer to www.pxisa.org




Glossary

R

range Region between the limits within which a quantity is measured, received, or transmitted. The range is expressed by stating the lower and upper range values.

T

tank task

S

scalar scale scatter graph scope serial slide slider smart tag switch synchronous

Number that a point on a scale can represent. The number is a single value as opposed to an array.

Part of graph, chart, and some numeric controls and indicators that contains a series of marks or points at known intervals to denote units of measure.

A control that displays two-dimensional data on a Windows Forms or Web

Forms user interface; displays a graph of X and Y data pairs.

See

oscilloscope

.

Standard serial bus on a computer used to communicate with instruments.

Also known as RS-232.


Moveable part of a slide control.

A glyph attached to a Measurement Studio control or component that exposes commonly performed tasks

.

A control used to receive and control Boolean input in an application user interface.

Property or operation that begins and returns control to the program only when the operation is complete.



NI-DAQmx—a set of channels and the channel configurations, timing, and triggering, and other details that define a measurement or generation you want to perform.

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Glossary

TCP/IP

TestStand

Transmission Control Protocol/Internet Protocol. A standard format for transferring data in packets from one computer to another. The two parts of

TCP/IP are TCP, which deals with the construction of data pockets, and IP, which routes them from computer to computer.

Ready-to-run test executive from National Instruments for organizing, controlling, and executing your automated prototype, validation, or manufacturing test systems.


thermometer

U

UI uplevel browser

W

waveform graph

User Interface.

Recent generation Web browser that supports rich client interaction and functionality. See also

downlevel browser .

V

vector 1D array.

virtual instrument (VI) Program in Measurement Studio that models the appearance and function of a physical instrument.

VISA Driver-software architecture developed by National Instruments to unify instrumentation software for serial, GPIB, and VXI instruments or controllers. It has been accepted as a standard for VXI by the

VXI plug&play Systems Alliance.

VXI VME eXtension for Instrumentation. Instrumentation architecture and bus based on the VME standard. Used in high-end test applications.

A control that displays two-dimensional data on a Windows Forms or Web

Forms user interface; displays data that is uniformly spaced in one dimension.



Index

A

ActiveX controls in Visual C++, 3-2

Add/Remove Class Libraries wizard, 4-5 adding or removing Measurement Studio class libraries, 4-5

Analysis

.NET class library, 2-2

Array and Numeric Operations

(table), 2-9

Curve Fitting (table), 2-10

Enterprise Analysis, 2-3

Filters (table), 2-5

Linear Algebra (table), 2-7

Measurements (table), 2-3

Professional Analysis, 2-2

Signal Generation (table), 2-4

Signal Processing (table), 2-6

Standard Analysis, 2-2

Statistics (table), 2-10

Windowing (table), 2-4

Visual C++ class library, 3-3

Array and Numeric Operations

(table), 3-10

Curve Fitting (table), 3-11

Enterprise Analysis, 3-4

Filters (table), 3-6

Linear Algebra (table), 3-8

Measurements (table), 3-5

Professional Analysis, 3-4

Signal Generation (table), 3-5

Signal Processing (table), 3-7

Standard Analysis, 3-4

Statistics (table), 3-12

Windowing (table), 3-6

AutoRefresh control, 2-49

B

button control, 3-19

C

Common



complex graph control, 2-25, 2-42

conventions used in the manual,

x

creating

Measurement Studio Application with

Web Forms Controls and Analysis in

Visual Studio 2005 (walkthrough), 5-11


Web Forms Controls and Network

Variable in Visual Studio 2005

(walkthrough), 5-31


Windows Forms Controls and Analysis

(walkthrough), 5-2


Windows Forms Controls and Network

Variable (walkthrough), 5-22

Measurement Studio Instrument I/O

Application (walkthrough), 5-52

Measurement Studio NI-DAQmx application, 4-6

Measurement Studio NI-DAQmx

Application (walkthrough), 5-42

new Measurement Studio project, 4-4

NI-DAQmx user code, 4-9

NI-DAQmx user interface, 4-8

© National Instruments Corporation I-1


Index

D

DAQ Assistant, 4-6

data acquisition (DAQ), 2-16, 3-17

DataSocket, .NET class library, 2-15

deployment requirements, 1-3

developing with Measurement Studio, 4-1

diagnostic tools (NI resources), A-1

digital waveform graph control, 2-23, 2-40

documentation

conventions used in the manual, x

how to use manual set,

ix

NI resources, A-1 drivers (NI resources), A-1

E

examples (NI resources), A-1

G

gauge control, 2-27, 2-44

graph control

3D, 3-2

ActiveX, 3-20

complex, 2-25, 2-42

digital waveform, 2-23, 2-40

scatter, 2-20, 2-38 waveform, 2-20, 2-38

H

help

NI Measurement Studio Help, 1-9

technical support, A-1

how to use manual set,

ix

I

installation

optional, 1-3

requirements, 1-2


I-2

instrument drivers (NI resources), A-1

Instrument I/O Assistant, 4-9

K

knob

.NET control, 2-28

.NET Web Forms control, 2-45

Visual C++ control, 3-21

KnowledgeBase, A-1

L

LED array control, 2-33

LED control, 2-30, 2-48

legend control, 2-27, 2-44

M

Measurement & Automation Explorer

(MAX), 4-2

Measurement Studio

developing with, 4-1

home page, 4-3

Menu, 4-1

overview, 1-1

package comparison chart, 1-7

Preferences, 4-4

resources, 1-9

meter control, 2-28, 2-45

Microsoft Excel Interface Visual C++ class library, 3-16

Microsoft Word Interface Visual C++ class library, 3-16

N

National Instruments support and services, A-1

.NET class libraries

Analysis, 2-2

ni.com

Common, 2-13

NI-488.2, 2-16

NI-DAQmx, 2-16

NI-SCOPE, 2-17

NI-VISA, 2-17

overview, 2-1

User Interface, 2-18, 2-37


Network Variable


NI DAQ Assistant, 4-6

NI Developer Zone, 4-4

NI Discussion Forums, 4-3

NI Instrument Driver Network, 4-3

NI Spy, 4-2

NI support and services, A-1

NI-488.2



NI-DAQmx

creating a DAQ application, 4-6



NI-Reports Visual C++ class library, 3-18

NI-SCOPE


NI-VISA



numeric controls, 2-27, 2-44

numeric edit

.NET control, 2-29, 2-47

Visual C++ control, 3-22

O

overview

Measurement Studio, 1-1

.NET class libraries, 2-1

Visual C++ class libraries, 3-1

© National Instruments Corporation I-3

Index

P

Parameter Assistant, 4-11

programming examples (NI resources), A-1

project conversion wizard, 4-2

project templates, 4-4

property editor control, 2-32

R

requirements

distribution, 1-3

installation, 1-2

S

scatter graph control, 2-20, 2-38

selecting a Measurement Studio parameter value, 4-11

slide control

.NET, 2-29, 2-46

Visual C++, 3-23

software (NI resources), A-1 support, technical, A-1

switch array control, 2-33

switch control, 2-30, 2-48

T

tank control, 2-29, 2-46

technical support, A-1

thermometer control, 2-29, 2-46

training and certification (NI resources), A-1 troubleshooting (NI resources), A-1

U

User Interface

.NET class library, 2-18, 2-37

AutoRefresh, 2-49

complex graph, 2-25, 2-42

digital waveform graph, 2-23, 2-40


Index

gauge, 2-27, 2-44

knob, 2-27, 2-44

LED, 2-30, 2-48

legend, 2-27, 2-44 meter, 2-27, 2-44

numeric edit, 2-29, 2-47

property editor, 2-32

scatter graph, 2-20, 2-38

slide, 2-29, 2-46

switch, 2-30, 2-48

tank, 2-29, 2-46 thermometer, 2-29, 2-46

waveform graph, 2-20, 2-38

Visual C++ class library, 3-19 button, 3-19

graph, 3-20

knob, 3-21

numeric edit, 3-22

slide, 3-23

Utility Visual C++ class library

CNiFile (table), 3-24

CNiSound (table), 3-24

CNiSystem (table), 3-24

CNiSystemTrayIcon (table), 3-24

CNiTempFile (table), 3-25

CNiTimer (table), 3-25

V

Variable Manager, 4-3

Visual C++ class libraries

3D graph, 3-2

Analysis, 3-3

Common, 3-15


Microsoft Excel Interface, 3-16

Microsoft Word Interface, 3-16

NI-488.2, 3-17

NI-DAQmx, 3-17

NI-Reports, 3-18

NI-VISA, 3-18

overview, 3-1

User Interface, 3-19

Utility, 3-24

W

walkthrough

Creating a Measurement Studio

Application with Webs Forms

Controls and Analysis in Visual

Studio 2005, 5-11


Application with Webs Forms Controls and Network Variable in Visual

Studio 2005, 5-31


Application with Windows Forms

Controls and Analysis, 5-2


Application with Windows Forms

Controls and Network Variable, 5-22


Instrument I/O Application, 5-52


NI-DAQmx Application, 5-42

waveform graph control, 2-20, 2-38

Web Forms user interface controls, 2-37

Web resources, A-1

Windows Forms array controls, 2-33

LED array control, 2-33 switch array control, 2-33

Windows Forms user interface controls, 2-18


I-4 ni.com

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