BEGIN:VCALENDAR VERSION:2.0 PRODID:-//132.216.98.100//NONSGML kigkonsult.se iCalcreator 2.20.4// BEGIN:VEVENT UID:20260523T032500EDT-2499ee4HDK@132.216.98.100 DTSTAMP:20260523T072500Z DESCRIPTION: \n\nAbstract\n\nMost modern communication systems employ sever al domains for transmission and reception such as space\, time\, frequency \, users\, code sequences\, and transmission media. Thus\, the signals and systems involved in information transfer have an inherent multi-domain st ructure which can be well represented using tensors. A tensor is a multi-w ay array which can be seen as a higher order generalization of vectors or matrices. A unified mathematical framework capable of intuitively modellin g multi-domain communication systems can be developed with the help of ten sors. The use of tensors to characterize\, analyze\, and build multi-domai n communication systems is proposed in this thesis. A generic system model is defined in this work for multi-domain communication systems with N inp ut domains and M output domains. The multi-linear channel between such hig her order input and output signals is defined as an order M+N tensor\, whi ch couples the input and output through the Einstein product. The suggeste d framework is generic\, where the physical interpretations of the domains can vary depending on the specific system being modelled.\n\nAn informati on theoretic analysis of multi-domain communication systems is considered by deriving the Shannon capacity and input power allocation for a fixed hi gher order tensor channel under a family of power constraints. Owing to th e multi-domain nature of the input signals\, the power constraints in mult i-domain communication systems can span one or more domains. This thesis d emonstrates the tensor framework's ability to mathematically represent a v ariety of such power constraints. Shannon capacity of tensor channels unde r such family of power constraints is derived. Water-filling is extended f rom a matrix setting to higher domains in such a tensor-based formulation\ , encapsulating the impact of various domains and allowing collaborative m ulti-domain precoding and power allocation. It is also shown that as the n umber of domains increases\, the multiplexing gain for a tensor channel ca n increase exponentially\, indicating the ability of the tensor-based comm unication systems to offer the enormous information transmission rates req uired for beyond 5G systems. In addition\, this thesis illustrates how the tensor framework can be used to characterize the capacity and rate region s of multi-user MIMO channels. The tensor-based technique leads to a coord inated users transmission scheme. The tensor framework treats the multi-do main interference terms as information bearing entities\, and thus ensures higher achievable sum rates as compared to the independent users transmis sions.\n\nFurther\, the Einstein Product of tensors is used to develop a f ramework for minimum mean square error (MMSE) estimation for multi-domain signals and data. Both proper and improper complex tensors are addressed b y the framework. The traditional linear and widely linear MMSE estimators are extended to the tensor setting\, resulting in multi-linear and widely multi-linear MMSE estimation. Further\, a relation between the MMSE error covariance tensor and the gradient of the mutual information is extended f rom a vector setting to tensors\, known as the tensor I-MMSE relation. Fur thermore\, the tensor I-MMSE relation is used to find the capacity of tens or channels when the input is drawn from arbitrary distributions. In the p resence of circularly symmetric Gaussian noise and under no constraint on the input constellation\, an input drawn from a circularly symmetric Gauss ian distribution achieves the channel capacity. However\, under practical scenarios\, the input is often drawn from discrete signalling constellatio ns which are far from Gaussian distributed. By making use of the tensor I- MMSE relation\, an iterative precoder is developed in this thesis which ac hieves capacity of the tensor channels when the input is limited by the ch oice of signalling constellations.\n DTSTART:20221003T180000Z DTEND:20221003T200000Z LOCATION:\, Room 603\, McConnell Engineering Building\, CA\, QC\, Montreal\ , H3A 0E9\, 3480 rue University SUMMARY:PhD defence of Divyanshu Pandey - Information theoretic aspects of tensor based multi-domain communication systems URL:/ece/channels/event/phd-defence-divyanshu-pandey-i nformation-theoretic-aspects-tensor-based-multi-domain-communication-34249 1 END:VEVENT END:VCALENDAR