Programming Examples

LAN Programming Interface Examples

2.At the UNIX prompt in your home directory type: cc -Aa-O-o lanio lanio.c

3.At the UNIX prompt in your home directory type: ./lanio xxxxx “*IDN?” where xxxxx is the hostname for the signal generator. Use this same format to output SCPI commands to the signal generator.

The int main1() function will output a sequence of commands in a program format. If you want to run a program using a sequence of commands then perform the following:

1.Rename the lanio.c int main1() to int main() and the original int main() to int main1().

2.In the main(), openSocket() function, change the “your hostname here” string to the hostname of the signal generator you want to control.

3.Re- save the lanio.c program.

4.At the UNIX prompt type: cc -Aa -O -o lanio lanio.c

5.At the UNIX prompt type: ./lanio

The program will run and output a sequence of SCPI commands to the signal generator. The UNIX display will show a display similar to the following:

unix machine: /users/mydir $ ./lanio

ID: Agilent Technologies, E4438C, US70000001, C.02.00

Frequency: +2.5000000000000E+09

Power Level: -5.00000000E+000

Sockets on Windows

In Windows, the routines send() and recv() must be used, since fread() and fwrite() may not work on sockets. The following steps outline the process for running the interactive program in the Microsoft Visual C++ 6.0 environment:

1.Rename the lanio.c to lanio.cpp and getopt.c to getopt.cpp and add them to the Source folder of the Visual C++ project.

NOTE The int main() function in the lanio.cpp file will allow commands to be sent to the signal generator in a line- by- line format; the user types in SCPI commands. The int main1(0) function can be used to output a sequence of commands in a “program format.” See Programming Using main1() Function below.

2. Click Rebuild All from Build menu. Then Click Execute Lanio.exe. The Debug window will appear with a prompt “Press any key to continue.” This indicates that the program has compiled and can be used to send commands to the signal generator.

3.Click Start, click Programs, then click Command Prompt. The command prompt window will appear.

4.At the command prompt, cd to the directory containing the lanio.exe file and then to the Debug folder. For example C:\SocketIO\Lanio\Debug.

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Agilent N518xA, E8663B, E44x8C, and E82x7D Signal Generators Programming Guide

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Agilent Technologies N5181A/82A, N5183A MXG, E8663B manual Sockets on Windows
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N5183A, N5183A MXG, E8663B, N5181A/82A specifications

Agilent Technologies is renowned for its innovative solutions in electronic test and measurement equipment. Among its offerings are several signal generators including the N5181A, N5182A, E8663B, and N5183A MXG. These models are distinguished not only by their performance but also by their versatility across various applications in communications, aerospace, and electronics.

The Agilent N5181A and N5182A, part of the MXG family, are highly versatile signal generators known for their exceptional frequency performance and flexibility. The N5181A operates from 100 kHz to 6 GHz, while the N5182A extends that range up to 12 GHz. They provide high fidelity signals with low phase noise, making them ideal for the development and testing of RF components and systems. These generators support a wide variety of modulation formats, including AM, FM, PM, and pulse modulation, catering to diverse application needs.

The E8663B, meanwhile, is designed for the range of 250 kHz to 3 GHz and is also recognized for its high-performance features. Its built-in capabilities for modulation make it effective for testing wireless devices, ensuring that signals can be simulated accurately in both laboratory and field environments. It is especially beneficial for users requiring a straightforward and efficient solution with high reliability.

The N5183A MXG signal generator enhances the lineup with frequency coverage up to 6 GHz and advanced capabilities. It integrates various modulation capabilities while ensuring high signal integrity. Its architecture is tailored for both production test environments and research applications, providing users with the flexibility to adapt to changing testing requirements.

Common characteristics across these models include a user-friendly interface that simplifies configuration and operation. They are often equipped with LAN and USB interfaces for easy remote control and integration into automated test systems. The robustness of these generators allows them to perform reliably in challenging environments, making them essential tools in laboratories, manufacturing floors, and field testing scenarios.

In summary, Agilent's signal generators, including the N5181A, N5182A, E8663B, and N5183A MXG, represent a blend of advanced technology, flexibility, and precision. These instruments are vital in facilitating the evolution of cutting-edge communication technologies, ensuring that designers and engineers can confidently meet the demands of modern electronics.
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