A Historic Milestone That Could Redefine the Future of Artificial Intelligence and Computing
The race toward the next generation of computing took a significant step forward on April 23, 2026, when Dr. Ko-Cheng Fang, Founder, Chairman, and CEO of LongServing Technology Co., Ltd., publicly revealed the company’s complete photonic chip system architecture, marking one of the most ambitious disclosures yet in the emerging field of optical computing.
Published through LongServing Technology’s official website, the announcement introduced three original engineering designs personally created by Dr. Fang: a 3D architectural diagram of the photonic chip, a detailed photonic pathway system, and, for the first time, a full-adder photonic chip structural demonstration. Together, these designs provide a comprehensive view of the company’s vision for replacing traditional electronic computation with light-based processing.
Unlike conventional semiconductor chips that rely on electrical signals traveling through billions of transistors, LongServing’s architecture is built around photons—the fundamental particles of light—designed to dramatically increase computational speed while reducing energy consumption and heat generation.
At the heart of the announcement is an entirely reimagined photonic circuit layout. Rather than following traditional horizontal electronic routing, Dr. Fang redesigned the optical pathways into an innovative 45-degree photonic architecture, creating a system intended to maximize signal efficiency while simplifying large-scale integration.
Even more striking is the chip’s vertical three-layer design.
The bottom layer functions as dedicated photonic memory, enabling optical data storage. The middle layer contains photonic logic gates, where computational operations are performed. The top layer serves as the optical highway, carrying high-speed photonic pathways that connect the entire system.

Each structural layer is manufactured using its own dedicated photomask, allowing the entire computing platform to operate with only three integrated layers—an approach that stands in sharp contrast to modern electronic chips, which typically require dozens of manufacturing layers to achieve similar complexity.
According to LongServing Technology, this architectural simplification represents a major step toward improving manufacturing efficiency while dramatically reducing system complexity.
Perhaps the most significant aspect of the announcement is the public introduction of the company’s full-adder photonic chip—one of the most fundamental building blocks in digital computing. Full adders perform binary arithmetic operations that underpin processors used in artificial intelligence, data centers, and modern computing systems.
By demonstrating a fully optical implementation of this essential computational element, LongServing provides a tangible example of how complete photonic processors may eventually perform advanced calculations without depending on conventional electronic circuitry.
The announcement also highlights another key component of Dr. Fang’s long-term vision: photonic memory.
Traditional computing constantly converts information between electrical and optical signals, introducing latency and energy loss throughout the process. LongServing’s proposed architecture seeks to minimize those conversions by storing and processing information directly in optical form, performing photoelectric conversion only at the final output stage.
If successfully commercialized, this approach could significantly improve computing efficiency while eliminating one of the major bottlenecks facing today’s AI hardware.
LongServing states that combining photonic memory with photonic processing has already demonstrated computational performance reaching hundreds of thousands of times faster than conventional electronic chips under its proposed architecture. Because photons travel at the speed of light, the company notes that the technology’s ultimate performance ceiling remains difficult to measure.

The announcement builds upon several years of research conducted by Dr. Fang across multiple scientific disciplines.
His portfolio includes patented cloud computing and cybersecurity technologies, laboratory-grown Imperial Green jadeite materials, biotechnology research, artificial intelligence robotics, and photonic quantum materials.
Among his most widely discussed innovations is X-Photon, a proprietary photonic quantum material designed to emit light at an ultra-short wavelength of approximately 2 nanometers. According to LongServing, this material forms the foundation for nanoscale photonic pathways and next-generation optical quantum chips.
The company has secured patent protection for its photonic technologies across 26 countries, reflecting its ambition to establish an international presence within the rapidly evolving semiconductor industry.
Beyond technology, Dr. Fang has developed an unusually multidisciplinary reputation that bridges science, engineering, entrepreneurship, biotechnology, fine art, and luxury design. His original paintings have been exhibited internationally—including a digital display in New York’s Times Square—and have inspired LongServing’s expansion into luxury fashion, where laboratory-grown jadeite is incorporated into handcrafted boutique collections.
This combination of scientific innovation and artistic creativity has earned comparisons to Renaissance-style inventors whose work transcends conventional academic boundaries.
As artificial intelligence continues to drive unprecedented demand for faster, more energy-efficient computing infrastructure, photonic computing has emerged as one of the industry’s most closely watched frontiers.
LongServing Technology is positioning itself as one of the companies seeking to help shape that future.
With its complete architectural disclosure, the company has moved beyond theoretical discussion and offered the public its first comprehensive look at an integrated photonic computing platform—one that aims to combine photonic memory, optical logic, and advanced system architecture into a unified design.
Whether this vision ultimately transforms the semiconductor industry will depend on future engineering validation, manufacturing scalability, and commercial adoption.
What is already clear, however, is that Dr. Ko-Cheng Fang’s latest announcement represents an ambitious contribution to one of the most important technological races of the 21st century—one where the future of artificial intelligence may ultimately be powered not by electricity, but by light.

























