This high capacity memory and data transport system removes memory-to-processor distance restrictions and bandwidth limitations imposed by copper transmission wiring.
About
High-Capacity Wireless Data Transmission and Memory Storage System: High-capacity memory systems like those in used in high-end servers, routers, mainframe computers, and supercomputers carry a massive amount of peripheral data that needs to be quickly and temporarily stored and accessed. Faster systems require greater amounts of memory in close proximity to the processor. A two-part dilemma arises in this high-capacity processor-to-memory transport equation: while the large number of data storage cells (such as SDRAM) require physical space and cannot be wired close to the processor, traditional wiring with copper transmission lines offers reduced bandwidth as the distance between the processor and memory increases. Millimeter Wave Wireless Data System Optimizes Distance and Bandwidth: This high capacity memory and data transport system removes memory-to-processor distance restrictions and bandwidth limitations imposed by copper transmission wiring. The system transmits data from memory to processor to memory by using extremely high frequency (EHF) radio waves, with wavelengths between one millimeter and one centimeter, to transport data over distances ranging from a few centimeters to a few meters., or in the frequency band of 30GHz to 300GHz. In addition, this network uses wireless radio frequency carrier wave transmission to store large amounts of distributed memory anywhere and access it anytime without bandwidth limitations or the use of copper transmission lines. This memory exchange system forms a network of memory stacks, processors, radio frequency transmitters and receivers, a network-wide optical clock that for synchronization, and a fixed, onboard phase delay line for each receiver. Because of its unique ability to move, store, and access large amounts of data for complex systems, this wireless memory system would work extremely well with a cyber-physical system like an integrated medical system used in robotic surgery. Applications: • Cyber-physical systems like integrated medical systems used in robotic surgery • High-end servers • Mainframe computers • Supercomputers • High-end routers • Router original equipment manufacturers Advantages: • Removes memory-to-processor distance restrictions • Removes bandwidth limitations • Low power consumption saves on operation costs • Expands the architecture options for the system • High bit rate for data transference • Optical clock decreases number of components required and energy dissipation