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.
Engineers in Prof. Sachin Katti's laboratory have developed a full duplex wireless system designed to double throughput by simultaneously transmitting and receiving signal on a standard single inband antenna.
Stanford researchers have developed a novel, inverse-designed wavelength division multiplexer (WDM) that integrates high-performance Bragg gratings for use in optical communication systems.
Stanford researchers have developed flat, ultrathin (sub 100nm) optical elements based on high index nanostructures which can be alternatives to refractive optical elements such as gratings, lenses, and axicons.
Quantum scientists in the LINQS, Schuster, and Simon Labs at Stanford have developed a method of multiplexing many low-light optical fields onto a single fast sensor.
Stanford Nanoscale and Quantum Photonics Lab researchers developed a passive, magnet free, integrated on-chip laser stabilization and isolation device. Lasers need a way to prevent the light they emit from reflecting into the laser and destabilizing it.
Researchers in The Optical Communications Group at Stanford have developed an efficient, integrated multimode optical amplifier for scalable, spatially multiplexed long-haul optical fiber transmission.
Active manipulation of light beams is required for a range of emerging optical technologies, including sensing, optical computing, virtual/augmented reality, dynamic holography, and computational imaging.
Researchers at Stanford are developing a device that uses quantum engineered states and interactions to detect electromagnetic waves with a sensitivity and bandwidth beyond that possible with existing technology.
Researchers at Stanford have developed methods for evaluating the position of a micro-electromechanical system (MEMS) device in terms of phase and/or amplitude characteristics.
Researchers at Stanford are advancing a new class of nonlinear optical devices that operate with significantly lower energy requirements than previous platforms.
Researchers in the Dionne group at Stanford have designed a nanoscale laser capable of self-isolated Raman Lasing, where lasing and isolation occurs within the same pumping mechanism.
Stanford researchers have developed a simple optical device for low-power, active light tuning. The device tunes the color of light across the visible spectrum and at select wavelengths by electrical biasing an array of micron sized pixels or nanowires.