@article{discovery10071648,
       publisher = {IEEE-INST ELECTRICAL ELECTRONICS ENGINEERS INC},
           pages = {3495--3501},
            note = {This version is the author accepted manuscript. For information on re-use, please refer to the publisher's terms and conditions.},
         journal = {Journal of Lightwave Technology},
           title = {Microwave Photonic Integrated Circuits for Millimeter-Wave Wireless Communications},
            year = {2014},
           month = {October},
          volume = {32},
          number = {20},
            issn = {1558-2213},
             url = {https://doi.org/10.1109/JLT.2014.2321573},
          author = {Carpintero, G and Balakier, K and Yang, Z and Guzman, RC and Corradi, A and Jimenez, A and Kervella, G and Fice, MJ and Lamponi, M and Chitoui, M and van Dijk, F and Renaud, CC and Wonfor, A and Bente, EAJM and Penty, RV and White, IH and Seeds, AJ},
        abstract = {This paper describes the advantages that the introduction of photonic integration technologies can bring to the development of photonic-enabled wireless communications systems operating in the millimeter wave frequency range. We present two approaches for the development of dual wavelength sources for heterodyne-based millimeter wave generation realized using active/passive photonic integration technology. One approach integrates monolithically two distributed feedback semiconductor lasers along with semiconductor optical amplifiers, wavelength combiners, electro-optic modulators and broad bandwidth photodiodes. The other uses a generic photonic integration platform, developing narrow linewidth dual wavelength lasers based on arrayed waveguide gratings. Moreover, data transmission over a wireless link at a carrier wave frequency above 100 GHz is presented, in which the two lasers are free-running, and the modulation is directly applied to the single photonic chip without the requirement of any additional component.}
}