Discover our comprehensive range of memory modules and custom PCB assemblies designed for modern telecommunication nodes and computing systems.
In the era of hyper-scale computing, 5G rollouts, and artificial intelligence, high-performance physical infrastructure is paramount. As a top China manufacturer and supplier of infrastructure technologies, Corexis Memory Technology Co., Ltd. co-develops next-generation systems linking optical transmission interfaces with ultra-fast edge processing nodes.
From single-mode long-haul fiber configurations to multi-mode high-density configurations in modern AI data centers, physical layer components dictate the absolute limits of signal latency and bandwidth capacity.
Our collaborative ecosystems ensure that fiber optic transmission and backend server memory process and move data seamlessly. This integration reduces bottlenecks, enabling hyper-scale data centers to achieve sub-millisecond transmission architectures.
Delivering fiber-to-the-home structures supporting GPON/XG-PON standards.
MTP/MPO fiber assemblies designed for ultra-dense 400G and 800G pathways.
Since our establishment in 2016, we have built a state-of-the-art facility spanning 21,800 m², integrating advanced R&D, SMT lines, and meticulous QA frameworks.







Leveraging ten years of industry expertise and eight years of export experience, we serve system integrators, OEM brands, and industrial equipment manufacturers in North America, Europe, Southeast Asia, South America, and the Middle East.
Our facility utilizes high-speed SMT assembly, automated optical inspection (AOI), and robust reliability testing parameters to ensure every component exhibits exceptional durability in extreme operating conditions.
Exploring the core technological transformations and procurement challenges faced by telecommunication operators and hyper-scale enterprise networks.
Global procurement teams must balance per-meter manufacturing costs against physical cable longevity. Low-smoke zero-halogen (LSZH) jacketing and bend-insensitive glass fibers (G.657.A2) prevent costly signal degradation and meet strict localized environmental codes.
Physical space constraints in municipal conduits and hyper-scale data centers have accelerated the adoption of ultra-dense micro-cables and ribbon fiber architectures. Managing hundreds of fibers in a single sheath requires precision geometry and advanced splicing designs.
With PAM4 and coherent optical transceivers becoming standard, physical cabling configurations must support very low insertion loss and high return loss. Integrating reliable cabling infrastructures directly mitigates data transmission errors.
Our engineering divisions focus on standardizing material choices, optical loss margins, and high-frequency PCBA designs to guarantee reliable end-to-end performance.
| Fiber / Component Type | Key Standards Compliance | Primary Application Areas | Optoelectronic Assembly Requirements |
|---|---|---|---|
| Single-Mode (G.652.D) | ITU-T G.652.D, IEC 60793-2-50 | Long-Haul WAN, Metro Core Networks | Low insertion loss adapters, precise termination interfaces |
| Bend-Insensitive Single-Mode | ITU-T G.657.A1 / A2, RoHS | FTTx, Structured Enterprise Racks | Minimum bend radius tolerance, durable SMT transceivers |
| Multi-Mode (OM3 / OM4 / OM5) | ISO/IEC 11801, TIA-568.3-D | Hyper-Scale Data Center Interconnects | High-bandwidth transceivers (VCSEL 850nm), DDR5 RAM caching |
| Optoelectronic PCBs | IPC-A-610 Class 3, UL 94V-0 | Optical Network Units (ONUs), Switches | Immersion silver finish, high SMT component density |
We deliver structural hardware assemblies and design frameworks for complex enterprise operations worldwide.
Modern AI workloads demand real-time data exchange across distributed GPU clusters. Standard Ethernet infrastructures are shifting to InfiniBand and ultra-dense MTP/MPO optical cabling configurations. Our high-frequency PCB assemblies and server-grade memory modules work alongside these optical pipelines to keep processors fed without network bottlenecks.
Upgrading municipal networks requires robust single-mode fibers that withstand harsh environmental changes. By utilizing G.652.D fiber sheathed in anti-rodent, moisture-proof outer jackets, utilities and operators minimize fiber degradation over decades of operation.
Providing high-speed internet to millions of endpoints requires reliable GPON and EPON architectures. From terminal boxes containing specialized splitters to customer-premises equipment (CPEs) built on our SMT/DIP motherboards, we support the hardware chain from exchange offices to residential living rooms.
In harsh factory environments, electromagnetic interference (EMI) makes copper cabling unreliable. Fiber optic networks provide complete electrical isolation, ensuring error-free communication. Combined with our industrial-grade PCBA modules, this setup delivers consistent control telemetry for advanced manufacturing equipment.
Our strict testing processes ensure every shipped unit complies with target market certifications.
Every shipment undergoes a multi-phase testing regimen, including Incoming Material Inspection (IQC), In-Process Inspection (IPQC), Final Quality Control (FQC), Outgoing Quality Assurance (OQA), and compatibility testing.
Our manufacturing practices prioritize ESG frameworks, utilizing RoHS and REACH compliant materials to ensure products meet localized environmental and safety laws.
We provide full customization, including private labeling, specialized packaging, circuit layout adjustments, capacity configurations, and high-conductivity thermal solutions, tailored to specific regional operational requirements.
Expert responses addressing standard industry specifications, manufacturing guidelines, and performance standards.
Single-mode fiber (typically OS2 with a core diameter of 9 microns) is designed for long-distance communication, utilizing a single laser path to transmit data over tens of kilometers with low signal loss. Multi-mode fiber (OM3, OM4, or OM5 with core diameters of 50 microns) is optimized for short distances, like data center cabinets, using multiple light paths to transmit high-density data over distances under 400 meters.
Bend-insensitive fibers feature a specialized glass layer that traps light even when the cable is tightly bent. This minimizes transmission losses in compact spaces like wall outlets or congested server racks, reducing maintenance requirements and down-time.
We employ a dedicated staff of 56 quality control personnel who oversee a five-tier testing framework. This includes material inspection (IQC), in-process testing (IPQC), final inspection (FQC), outgoing verification (OQA), and reliability and compatibility testing before shipment.
We provide full hardware design services, including custom PCB layout, firmware optimization, private labeling, specialized packaging, and custom thermal solutions to meet specific regional requirements.
Our products are manufactured to meet CE, FCC, RoHS, and REACH requirements, ensuring easy import and regulatory compliance in North America, Europe, South America, and Asia.
Explore our high-performance desktop, notebook, and server RAM modules designed to work alongside fast fiber optic networks.