The NI PXIE-8861 is a high-performance embedded controller from National Instruments (NI) designed for PXI (PCIe Extensions for Instrumentation) systems. Here is a breakdown of its parameters, specifications, dimensions, weight, series, features, and functions in English:
Parameters and Specifications:
Processor: Based on the Intel Core i7-7700TE, a quad-core processor with a clock speed of 2.9 GHz.
Memory: Typically equipped with 8GB DDR4 RAM for fast data processing.
Storage: 128GB SSD provides ample storage space for applications and data.
Operating System: Supports Windows 10 IoT Enterprise, enabling the use of Windows-based applications.
Dimensions and Weight:
Dimensions: Approximate dimensions are 229mm (length) x 151mm (width) x 53mm (height).
Weight: The exact weight is not specified, but it is expected to be within a manageable range for installation in a rackmount system.
Series:
The NI PXIE-8861 belongs to the NI’s PXI series of modular instrumentation controllers, designed for use in test, measurement, and automation applications.
Features:
Modular Design: Integrates into PXI systems, providing a modular approach to instrumentation and control.
Performance: High-performance processor and memory enable complex control and data processing tasks.
Connectivity: Offers various interfaces such as Gigabit Ethernet, USB, DisplayPort, and HDMI for connecting to peripherals and networks.
Power Supply: Compatible with a wide range of power inputs (100-240VAC, 50/60Hz), making it suitable for international use.
Remote Access: Supports remote control and monitoring through software-transparent links, enabling users to control the PXI system from a PC or laptop.
Functions/Applications:
Test and Measurement: The NI PXIE-8861 is commonly used in electronic device testing, communication equipment testing, and RF testing.
Automation Control: It can be used in industrial automation systems to control and monitor production lines, machinery, and other automated processes.
Data Acquisition and Processing: Its high-speed and high-precision capabilities make it suitable for data acquisition and processing tasks in laboratories, data recording, and monitoring applications.
Communications: It can be used for testing and validating communication devices, radios, and network equipment.
Education and Research: Supports various experiments and research projects in academic laboratories, research institutions, and educational institutions.
