Explores the fundamentals of mixers in low-power radio design for the IoT, covering types, characteristics, and detailed analyses of the single balanced mixer.
Explores optomechanical squeezing, where radiation pressure modifies light beam quantum properties, leading to complex correlations and experimental demonstrations.
Explores homodyne receivers, covering DC offset, channel selection, and offset cancellation, along with challenges like even-order distortion and LO leakage.
Explores homodyne detection in optomechanics, addressing limitations of diode rectification and showcasing the advantages of homodyne detection over traditional methods.
Explores sum frequency generation and second harmonic generation, emphasizing phase matching and birefringent crystals for efficient frequency conversion.
Covers the fundamental concepts of laser operation, including dispersion theory, gain and resonators, different types of laser systems, noise characteristics, optical fibers, ultrafast lasers, and nonlinear frequency conversion.
Explores the fundamental concepts of modes and states in quantum optics, covering topics such as optical frequency combs, homodyne detection, and quantum resource like squeezed states.
