Research Fields:

Space Science Instruments and Advanced Tests:

This field plays a crucial role in addressing frontier scientific challenges in space exploration. By tackling issues related to the space physical environment, electromagnetic environment, and information perception, the field seeks to innovate new detection and testing principles and methods, develops new space scientific observation instruments and scientific payloads, and advances space exploration, development, and utilization. The main research directions include: coupling effects and simulation of electromagnetic environments and structures, plasma sheath simulation for high-speed targets and experimental techniques in electromagnetic science, numerical simulation of space environmental effects and multiphysics fields, and space exploration and micro/nanosatellite engineering.

Vehicle TT&C and Space Information Processing:

This field utilizes advanced measurement and sensing means to enhance the overall information processing capabilities of aircraft. To meet the needs of developing new high-speed aircraft in China, the field focuses on theoretical frontier issues related to information acquisition, processing, transmission, and control of high-speed, highly dynamic moving targets in complex space environments. This entails tackling a variety of new challenges in measurement, control, and communication, as well as target identification and countermeasures in the high-speed flight environment of near space. This also includes exploring the basic problems intelligent collaboration in air-space-ground integrated information networks. The main research directions include space vehicle measurement, control and communication; space information countermeasures; and advanced navigation and guidance control for aircraft.

Aerospace Electronic Systems and Extreme Condition Detection Technology:

This field is an aerospace application and expansion of traditional electronics, especially detection technology. It is mainly focused on all types of space missions, including suborbital flights, earth orbit operations, shuttling between the space and the ground, missions to other planets, deep space exploration, and other complex space environments. This involves various tasks such as physical quantity detection, scientific exploration, image perception, and the acquisition, transmission, and intelligent processing of information from the spacecraft itself. Additionally, the field continually seeks to explore new principles, technologies, and integrated innovation models in aerospace electronics technology. It mainly involves extreme physical quantity detection, weak signal detection, aerospace electronic system design, aerospace reliability management, aerospace intelligent interconnection, and the integrated application of aerospace and commercial electronic technologies. The goal is to develop talents with practical skills in aerospace system design and research innovation capabilities.

Space Precision Measurement and High-end Equipment Instruments:

This field plays a crucial role in advancing space science and technology. To address the high-precision measurement needs in space exploration, it focuses on studying detection and information processing methods for weak targets in space, as well as measurement and detection techniques for accurately determining the relative poses of satellite formations. The goal is to establish a new space measurement system, develop precision measurement instruments for space, and enhance overall space exploration capabilities. The main research directions include: space faint target information processing, high-precision space detection principles and methods, satellite formation relative pose detection technology, space target interferometric imaging and image processing technology, and space precision instrument design.

Aerospace Sensors and Intelligent Sensing:

This field is a cutting-edge characteristic branch in the research field of Sensing and Detection Technology. This research focuses on aerospace applications and major national strategic needs, tackling various sensing challenges related to extreme physical quantities in complex environments. It involves the preparation and testing of new flexible functional materials and the design and manufacturing of new flexible micro-nano sensors. The goal is to explore intelligent sensing applications in aerospace, establishing a new research direction tailored to this field. Ultimately, it aims to provide a theoretical foundation and technical support for addressing sensing challenges in extreme aerospace environments.