The advancement of technology over the decades has been mind boggling and the latest in the march of advancement is the discovery of the nanophotonic switches by IBM researchers.I recently came to know about it from the ELECTRONICS FOR YOU magazine.Here i would like to briefly share this information.Another significant advance in IBM'''s quest to develop next generation high-performance multi-core computer chips which transmit information internally using pulses of light travelling through silicon instead of electrical signals on copper wires.
IBM scientists have developed the world's tiniest nanophotonic switch with a footprint about 100X smaller than the cross section of a human hair. With this development, IBM scientists have taken another significant advance towards sending information inside a computer chip by using light pulses instead of electrons. The nanophotonic switch is claimed to be an important building block to control the flow of information inside future chips and can significantly speed up the chip performance while using much less energy.
“This new development is a critical addition in the quest to build an on-chip optical network,” said Yurii Vlasov, manager, silicon nanophotonics, TJ Watson Research Center, IBM. “In view of all the progress that this field has seen for the last few years it looks that our vision for on-chip optical networks is becoming more and more realistic”.
In a paper published in the journal Nature Photonics, IBM unveiled the development of a silicon broadband optical switch, another key component required to enable on-chip optical interconnects. Once the electrical signals have been converted into pulses of light, this switching device performs the key role of 'directing traffic' within the network, ensuring that optical messages from one processor core can efficiently get to any of the other cores on the chip.
The IBM team demonstrated that their switch has several critical characteristics which make it ideally suited to on-chip applications. First, the switch is extremely compact. As many as 2,000 would fit side-by-side in an area of one sq.mm, easily meeting integration requirements for future multi-core processors.
Second, the device is able to route a huge amount of data since many different wavelengths or 'colours' of light can be switched simultaneously. With each wavelength carrying data at up to 40 Gb/s, it is possible to switch an aggregate bandwidth exceeding 1 Tb/s -- a requirement for routing large messages between distant cores.
Last but not least, the optical switch is capable of operating within a realistic on-chip environment, where the temperature of the chip itself can change dramatically in the vicinity of 'hot-spots', which move around depending upon the way the processors are functioning at any given moment. IBM scientists believe this temperature-drift tolerant operation to be one of the most critical requirements for on-chip optical networks.
An important trend in the microelectronics industry is to increase the parallelism in computation by multi-threading, by building large scale multi-chip systems and, more recently, by increasing the number of cores on a single chip. For example, the IBM Cell processor which powers Sony’s PlayStation 3 gaming console consists of nine 'brains', or cores, on a single chip. As users continue to demand greater computing performance, chip designers plan to increase this number to tens or even hundreds of cores.
This approach, however, only makes sense if each core can receive and transmit large messages from all other cores on the chip simultaneously. The individual cores located on today’s multi-core microprocessors communicate with one another over millions of tiny copper wires. However, this copper wiring would simply use up too much power and be incapable of transmitting the enormous amount of information required to enable massively multi-core processors.
IBM researchers are exploring an alternative solution to this problem by connecting cores using pulses of light in an on-chip optical network based on silicon nanophotonic integrated circuits. Like a long-haul fibre-optic network, such an extremely miniature on-chip network will transmit, receive and route messages between individual cores that are encoded as a pulses of light. It is envisioned that using light instead of wires, as much as 100 times more information can be sent between cores, while using 10 times less power and consequently generating less heat.
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