- 8 May 2006 -

Technique eliminates expense of actively aligning devices

A novel new hybrid assembly technique which offers a very simple yet highly reliable method of integrating optical devices, has been developed at the Centre for Integrated Photonics (CIP). The field-proven technique eliminates the expense of actively aligning devices - the process in common use today - providing a cost-effective platform for creating the sophisticated building-blocks required for advanced optical networking.
"Hybrid integration is an optimal way forward for many of the optical functions needed in advanced optical networks, but most of the assembly techniques in mainstream use today rely on highly skilled labour and expensive equipment, and do not scale," says Graeme Maxwell, CIP's VP of Hybrid Research & Development. "Our technique requires just passive assembly, yet provides very low insertion losses - making it possible to create single-module solutions for applications such as packet switches and signal regenerators".

The technique integrates by means of plugging silicon daughterboards carrying individual optical components into a planar silica motherboard - each having precision-machined mating faces. The components themselves also employ simple interface modifications - namely mode expansion, and features to support precision cleaving. The result turns hybrid photonic integration into a similar form of process to that used for assembling electronic PCBs - with the planar silica motherboard providing the equivalent of printed wiring.

The assembly technique has been developed and refined over a timespan of some 10 years, and has been highly optimised for low interface losses and ease of assembly, and does not involve any complex processing or etching. The technique is also highly scalable, and applies equally well to two devices or a large subsystem integrating many component elements.

CIP has manufactured numerous devices using the technique, such as its 2R regenerator - a recently announced commercial device that is attracting a lot of interest from optical network developers. On this example of its hybrid integration, the component integrates a planar silica Mach-Zehnder interferometer (MZI) and a monolithic quad semiconductor optical amplifier (SOA) array to create a dual-channel 2R regenerator with just a 1dB loss at daughterboard/motherboard interfaces.

The assembly technique has evolved from considerable research and development undertaken by CIP staff during the business' history as part of BT, then Corning and, for the last two years, as an independent photonic design and manufacturing consultancy. CIP offers the technology in a variety of forms to suit different applications and users. These include technology consultancy to support design-in, funded development programs, and the provision of turnkey hybrid component solutions - such as its multi-channel 2R regenerator.

"We believe this hybrid integration technique provides the performance, reliability and economy to address many of the sophisticated component functions necessary for advanced optical switched fabrics", adds Maxwell. "Among the potential applications are reconfigurable add-drop multiplexers, 2R and 3R signal regenerators, high-speed interconnect, packet switches, WDM PON devices and optical buffer memories. In each of these cases I expect our platform approach to offer considerable cost reduction and performance advantages over current component solutions and integration methods".

www.ciphotonics.com