Contents Up until recently, the terahertz frequency range (0.3 to 3THz) has been mostly addressed by high-mobility custom III-V processes, bulky and expensive nonlinear optics, or cryogenically cooled quantum cascade lasers. A low-cost room temperature alternative will enable a wide range of applications in security, defense, ultra-high-speed wireless communication, sensors, and biomedical imaging not currently accessible due to cost and size limitations. CMOS can potentially provide such a low-cost platform, but it requires novel techniques and architectures to generate, manipulate, radiate, and detect signals above transistor fmax, which are in the sub-THz frequency region in most of today's nodes.
Abstract:
Up until recently, the terahertz frequency range (0.3 to 3THz) has been mostly addressed by high-mobility custom III-V processes, bulky and expensive nonlinear optics, or...Show MoreMetadata
Abstract:
Up until recently, the terahertz frequency range (0.3 to 3THz) has been mostly addressed by high-mobility custom III-V processes, bulky and expensive nonlinear optics, or cryogenically cooled quantum cascade lasers. A low-cost room temperature alternative will enable a wide range of applications in security, defense, ultra-high-speed wireless communication, sensors, and biomedical imaging not currently accessible due to cost and size limitations. CMOS can potentially provide such a low-cost platform, but it requires novel techniques and architectures to generate, manipulate, radiate, and detect signals above transistor fmax, which are in the sub-THz frequency region in most of today's nodes.
Published in: 2012 IEEE International Solid-State Circuits Conference
Date of Conference: 19-23 February 2012
Date Added to IEEE Xplore: 03 April 2012
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California Institute of Technology, Pasadena, CA, USA
California Institute of Technology, Pasadena, CA, USA
California Institute of Technology, Pasadena, CA, USA
California Institute of Technology, Pasadena, CA, USA
