Photonic data transfer requires a light source (laser) to generated light pulses representing the bits which are transfered. Lasers for this purpose can only be created by using a special type of semiconductive material (the so-called III-V) materials, one of them is Indium Phosphide (InP). However, to make the lasers generate lightpulses at extremely high frequencies, they need to be electronically driven and controlled. This can only be efficiently done using electronic chips made in another semiconductive material, silicon (Si). Unfortunately, lasers cannot be made in Si. In turn, electronic circuits cannot be efficiently made in InP. So, to obtain the required function for high-speed communication, a combination of a Si and an InP chip must be made. Currently, the two chips are mounted next to each other onto a board, while they are electrically connected by small wires. It appears that this limits the transmission speed of the device, it requires costly mounting of the separate components onto the board and the device becomes bigger than desired. So, mounting the chips on top of each other enables a more compact solution and allows very short interconnection wiring which, in turn, allows a larger transmission rate of data.
The technology as developed within the WIPE-project however can be wider applied than just datacom applications. In every device where PICs and ICs must be combined, the WIPE solution is an option to create more compact, better performing and cheaper solutions.
Many parties can benefit from the WIPE-technology. It opens the market for new devices which could not be obtained because traditional technologies are too lumpy, too expensive or too energy consuming. The technology will also provide an impulse to the European photonic integration industry; Europe has been active in this field for many years and is running several years ahead of competitors. However, the lack of an adequate integration technology of ICs and PICs has been a draw back. The partners cooperating in WIPE hope that this technology will boost industry and academia to expand their commercial and research activities in integrated photonics.