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Rapid developments in computer science have led to the increasing demand for efficient computing systems. Linear photonic systems rose as a favorable candidate for workload-demanding architectures, due to their small footprint and low energy consumption. Mach Zehnder Interferometers (MZI) serve as the foundational building block for several photonic circuits, and have been widely used as modulators, switches and variable power splitters. However, combining MZIs for realizing multiport splitters remains a challenge, since the exponential increase in the number of devices and the consequential increase in losses is limiting the performance of the MZI based multiport device. To overcome such limitations, incorporating alternative and low loss integration platforms combined with a generalized design of the MZI could allow the realization of a robust variable power splitter. In this work, we present for the first time a 4×4 Generalized Mach Zehnder Interferometer (GMZI) incorporated on a Si3N4 photonic integration platform and we experimentally demonstrate its operation as a variable power splitter. We developed an analytical model to describe the operation of the 4×4 GMZI, allowing us to evaluate the impact of several parameters to the overall performance of the device and investigate the device’s tolerance to fabrication imperfections and design alternations. Its experimental evaluation as a variable power splitter reveals a controlled imbalance that ranges up to 10 dB in multiple output ports of the device, validating the theoretically derived principles of operation.
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