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The wireless spectrum is increasingly fragmented due to the growing proliferation of unlicensed wireless devices and piecemeal licensed spectrum allocations.

Wireless spectrum is increasingly fragmented due to the growing proliferation of unlicensed wireless devices and piecemeal licensed spectrum allocations.

Engineers in Prof. Sachin Katti's laboratory have developed a 3 X 3 in-band full duplex MIMO radio, that can simultaneously transmit and receive on the same channel using standard WiFi 802.11n PHY for 20 Mhz bandwidth.

Stanford researchers have invented techniques to adaptively tune the operation of a wireless full-duplex node. To enable full-duplex operation, the receiver circuit needs to be able to cancel the transmitter's signal in order to receive data from other nodes.

Stanford researchers have proposed two learning techniques for MIMO secondary users (SU) to spatially coexist with Primary Users (PU). Today, most of the spectrum is allocated to primary users for exclusive use.

Stanford researchers have proposed the use of feedback to improve point-to-point radio performance under a total energy constraint.

Stanford inventors have developed a method to incorporate machine learning algorithms to apply to signal detection in communication system receivers.

Stanford researchers have developed a low-power coherent optical receiver for high-speed data transmission between or within data centers.

Stanford researchers and Cray Inc. have patented a highly efficient system and method for routing packets in a multiprocessor computer system.

Researchers in Prof. William Dally's laboratory have developed a novel, cost-efficient topology for high-radix networks.

Researchers in Prof. William Dally's laboratory have designed a dragonfly topology that reduces the cost of high-radix networks by reducing the number of long, global cables.

Stanford researchers have developed an efficient and low-cost device which increases the energy harvest of a system by recovering these losses through module-level maximum power point tracking (MPPT).

The performance of most digital systems today is limited more by their communication or interconnection rather than their logic or memory. To increase the entire system's efficacy, the focus is on improving the system's interconnection network.

Stanford researchers have developed an innovative method for providing improved network services to mobile users.

Stanford researchers have developed novel systems and methods for power-controlled shared channel access in wireless networks supporting packetized data traffic.