Strategic Partnership to Advance Automotive Optical Communications for Future Network Demands Madrid (Spain)
KDPOF (leading supplier for high-speed connectivity over fiber optics in harsh environments) proudly announced their strategic partnership with Hinge Technology (China-based leader in advanced vehicle electronics architecture) to solve key technical issues in the industrial application of optical communications in vehicles.
For the development and mass production of in-vehicle electrical and electronic architecture of optical fiber communications, Hinge Technology utilizes ICs from KDPOF to design integrated optical modules combined with automotive-grade connectors and optical fiber harnesses to design the electrical electronic architecture (EEA).
“The widespread application of optical communications in automotive production faces challenges, including harsh environmental conditions and tough requirements for low cost and high reliability,” stated Yang Jun, CTO of Hinge Technology. “Our collaboration with the leading upstream supplier, KDPOF, accelerates the industrialization of vehicle communications system products based on 1 to 50 Gbps optical communications.”
Carlos Pardo, CEO and Co-founder of KDPOF added: “We’re proud that Hinge Technology has chosen our transceiver ICs for optical gigabit connectivity in harsh environments. At the recent Automotive Ethernet Summit in Shanghai, China, we showed our first joint project: a plastic optical fiber camera by Hinge Technology based on our well-proven KD1053 IC and integrated KD9351 FOT (fiber optic transceiver).”
Surround View System with High-speed Fiber Optics Camera
Using KDPOF components, Hinge Technology has developed an optical fiber camera. It can be paired with an optical fiber surround view host, resulting in a high-speed optical communications 360-degree surround view system or a reverse image system. The camera utilizes a 2MP high-quality image sensor for data collection, which is processed and transmitted via plastic optical fiber to the controller for image display or processing. Optical fiber cameras can achieve a stable transmission distance of up to 40 meters and deliver high-definition, real-time images. By comparison, LVDS coaxial cameras have no relay transmission capability and are limited to 15 meters.
The KDPOF EVB9351AUT evaluation board provides an extensive platform for testing the KDPOF KD9351 and KD1053 transceivers, designed for the 1000BASE-RHC PHY implementation in automotive optical networks. The KD9351 IC, with dimensions of 7 mm x 8 mm in an LGA-36 package, handles the PMD sublayer of the physical layer. The KD1053, sized at 7 mm x 7 mm in a QFN-56 package, manages both the PCS and PMA sublayers as specified by IEEE Std 802.3bvTM-2017. This setup supports data transfer rates of 1,000 and 100 Mbps.
Additionally, the board features an SFP slot, enabling it to serve as a media converter between the optical 1000BASE-RHC port and various SFP modules. These can include 1000/100BASE-T, 100BASE-FX, 1000BASE-S/LX, direct-attach passive twinax cable, and passive serial loopback configurations.
Joint Research and Design for Future Optical Connectivity
In addition to developing optical EEA for vehicle communications, KDPOF and Hinge Technology will extend their partnership to the application of optical communications technology in battery management systems (BMS) for electric vehicles. The companies are collaborating on the development and manufacturing of optical modules and system-on-chips (SoC). They plan to introduce optical-electronic integrated chip packaging technology in regions of China with well-developed automotive industry clusters, establishing FAB facilities capable of packaging chips with bandwidths ranging from 1 to 10 gigabits.
Utilizing Chiplet technology solutions, they are jointly researching and developing advanced chip-on-panel (COP) packaging technology for low-cost, high-reliability optical processors, optical modules, and complementary optical components tailored for automotive optical communications. This initiative aims to ensure production capacity for various automotive optical communications products. Together they plan to develop and manufacture higher-bandwidth optical communications semiconductors in the future, driving continuous upgrades of EEA architecture for the global automotive industry.
Furthermore, Hinge Technology conducts relevant functional verification on mass-produced vehicle models, including assessing packet loss rates, signal transmission losses, optical module heat dissipation, optical module and optical connector optical path coupling solutions, and optical connection reliability in various road environments. Based on the results of real vehicle verification, Hinge Technology develops corresponding solutions and provides feedback on technical issues related to optical chips to KDPOF for resolution.