Under the umbrella of Foxconn's 3 + 3 vision, HHRI Cybersecurity Research Center aims to initiate research in advanced ICT technology and empower Foxconn's products with security capability. Our research covers modern cryptographic techniques, cutting-edge mitigation methods of emerging cyberattacks, and state-of-the-art cybersecurity governance. With Foxconn's commitment to building autonomous mobility for the future, we endeavor to develop and provide concrete and robust security solutions.
Artificial intelligence (AI), as a fast-expanding research field, is rapidly evolving with broad applications. Our center aims to drive innovation, solve critical problems, and meet the needs for developing future product for Hon Hai. Currently, we focus on technologies of computer vision, scene understanding, natural language processing and their applications to the various fields including electric vehicles, digital health and robotic.
We aim to cultivate talents for Taiwan's semiconductor industry, and to develop advanced semiconductor technology. Researchers at the Semiconductor Research Center have mainly focused on compound semiconductor devices, silicon photonics, nanomaterials, advanced packaging technologies and applications of meta-optics. The Semiconductor Research Center is positioned as a technology-enabled institute, catalyzing the breakthrough innovation in the field of semiconductor with partners from the industry, academia, and government.
The next-generation wireless communications will cover the demands for cellular networks as well as internet of things. Varieties of new type applications would be inspired by the communications features in high data rate, low latency, massive connections, and ubiquitous coverage capabilities. The Next-generation Communications Research Center is committed to development of the enabling technologies for beyond 5G and 6G, especially in the area of intelligent vehicle-to-everything and the low earth orbit satellite communications. We hope to provide ubiquitous smart networks with flexible architecture to support various types of communications. We are devoted to innovations for value creation and industry advances.
The Quantum Computing Research Center will focus on developing quantum algorithms that are more efficient than the corresponding classical algorithms. We will also design fault-tolerant quantum computation schemes to overcome the noise issues of quantum hardware. Finally, we will seek quantum advantages for various application domains, including but not limited to material and drug discovery, quantum metrology, and quantum cryptography.
Trapped-Ion Quantum Computing Laboratory is committed to building a universal quantum computer based on trapped atomic ions. We explore from core quantum control theories of atomic physics and quantum optics, to scalable architectures, and to key enabling technologies R&D including semiconductor-based ion trap chips integrating MEMS, nano-electronics, and nano-photonics.