Tiny, wireless antennas use light to monitor cellular communication
As part of a high-resolution biosensing device without wires, the antennas could help researchers decode intricate electrical signals sent by cells.
As part of a high-resolution biosensing device without wires, the antennas could help researchers decode intricate electrical signals sent by cells.
By snugly wrapping around neurons, these devices could help scientists probe subcellular regions of the brain, and might even help restore some brain function.
The system could be used for battery-free underwater communication across kilometer-scale distances, to aid monitoring of climate and coastal change.
By synchronizing media streams transmitted from the cloud to two devices, researchers could improve cloud gaming and AR/VR applications.
A Lincoln Laboratory team visited Hill Air Force Base in Utah to determine how susceptible the latest-generation mobile network is to detection, geolocation, and jamming.
PhD student Will Sussman studies wireless networks while fostering community networks.
By keeping data fresh, the system could help robots inspect buildings or search disaster zones.
The prize is the top honor within the field of communications technology.
The device could help workers locate objects for fulfilling e-commerce orders or identify parts for assembling products.
A wireless technique enables a super-cold quantum computer to send and receive data without generating too much error-causing heat.
Fadel Adib uses wireless technologies to sense the world in new ways, taking aim at sweeping problems such as food insecurity, climate change, and access to health care.
MIT researchers demonstrate an intracellular antenna that's compatible with 3D biological systems and can operate wirelessly inside a living cell.
By continuously monitoring a patient’s gait speed, the system can assess the condition’s severity between visits to the doctor’s office.
Design from the Swager Lab uses electronic polymers, rather than colored lines, to indicate a positive response, enabling quantitative monitoring of biomarkers.
An MIT-developed device with the appearance of a Wi-Fi router uses a neural network to discern the presence and severity of one of the fastest-growing neurological diseases in the world.