Researchers, including one of Indian origin, have demonstrated the most complex 2-D optical phased array ever that can generate high-resolution beam patterns.
The new 2-D optical phased array technology will enable advanced Light Detection And Ranging (LADAR) and other defence applications.
LADAR provides a more detailed level of information that can be used for applications such as rapid 3-D mapping.
The array, which has dimensions of only 576 micro metre x 576 micro metre, roughly the size of the head of a pin, is composed of 4,096 (64 x 64) nanoantennas integrated onto a silicon chip.
Key to this breakthrough was developing a design that is scalable to a large number of nanoantennas, developing new micro-fabrication techniques, and integrating the electronic and photonic components onto a single chip.
“Integrating all the components of an optical phased array into a miniature 2-D chip configuration may lead to new capabilities for sensing and imaging,” said Sanjay Raman, program manager for DARPA’s Diverse Accessible Heterogeneous Integration (DAHI) program.
“By bringing such functionality to a chip-scale form factor, this array can generate high-resolution beam patterns -- a capability that researchers have long tried to create with optical phased arrays.
“This chip is truly an enabling technology for a host of systems and may one day revolutionise LADAR in much the same way that ESAs revolutionised RADAR. Beyond LADAR, this chip may have applications for biomedical imaging, 3D holographic displays and ultra-high-data-rate communications,” said Raman.
Radio frequency (RF) waves travel through the atmosphere, reflect off of a target, and return to the RADAR system to be processed.
The amount of time it takes to return correlates to the object’s distance. In recent decades, this technology has been revolutionised by electronically scanned arrays (ESAs), which transmit the RF waves in a particular direction without mechanical movement.
Each emitter varies its phase and amplitude to form a RADAR beam in a particular direction through constructive and destructive interference with other emitters.
Similar to RADAR, laser detection and ranging, or LADAR, scans a field of view to determine distance and other information, but it uses optical beams instead of RF waves.