July 26, 2021 - The SDVoE Alliance® today announced that Apantac, a leading provider of technology solutions for the broadcast and Pro AV industries, has joined the SDVoE Alliance as an adopting member.
"We recognize the importance of AV over IP in our industry and after careful examination of the many standards, we came to the conclusion that SDVoE has the highest quality and reliability," comments Thomas Tang, President of Apantac. "We have some exciting signal processing and extension products based on SDVoE in our roadmap and we look forward to delivering the highest quality to our customers, as well as providing the right technology solutions to our integrators to help them simply their workflows."
"We welcome Apantac to the SDVoE Alliance and look forward to working with them and their extensive global network of resellers and system integrators as they bring their SDVoE products to market," said Justin Kennington, president of the SDVoE Alliance. "Apantac’s reputation for delivering flexible and innovative technology solutions to their customers aligns perfectly with our vision for the SDVoE ecosystem."
Apantac’s first products that address the SDVoE ecosystem are a family of SDM modules including a 12G SDI Receiver and a UHD HDBaseT Receiver. Apantac’s expertise covers a vast range of applications including multiviewers & video walls, KVM over IP, fiber extension over IP and a wide range of signal processing solutions that address many applications.
All AV distribution and processing applications that demand zero-latency and uncompromised video can benefit from SDVoE technology, which provides an end-to-end hardware and software platform for AV extension, switching, processing and control through advanced chipset technology, common control APIs and interoperability. SDVoE network architectures are based on off-the-shelf Ethernet switches, thus offering substantial cost savings and greater system flexibility and scalability over traditional approaches, such as point-to-point extension and circuit-based AV matrix switching.