This paper fully determines the degree-of-freedom (DoF) region of two-user interference channels with arbitrary number of transmit and receive antennas in the case of isotropic and independent (or block-wise independent) fading, where the channel state information is available to the receivers but not to the transmitters. The result characterizes the capacity region to the first order of the logarithm of the signal-to-noise ratio (SNR) in the high-SNR regime. The DoF region is achieved using random Gaussian codebooks independent of the channel states, which implies that it is impossible to increase the DoF using beamforming and interference alignment in the absence of channel state information at the transmitters. Index Terms Capacity regio...
We provide inner bound and outer bound for the total number of degrees of freedom of the K user mult...
We explore the available degrees of freedom (DoF) for the two user MIMO interference channel, and fi...
We consider a single hop interference network with K transmitters, each with an independent message ...
Abstract—We provide the characterization of the degrees of freedom (DOF) region for a 2-user fading ...
This paper gives the approximate capacity region of a two-user MIMO interference channel with limite...
This paper gives the approximate capacity region of a two-user MIMO interference channel with limite...
interference and cognitive radio channels are studied under the assumption of no channel state infor...
Abstract—While the outer-bound of sum degrees of freedom (DoF) of 3-user interference channel is kno...
Abstract — We provide achievability as well as converse results for the degrees of freedom region of...
Abstract — In this paper, we provide a lower and upper bound for the number of degrees of freedom (D...
We characterize the degrees of freedom (DoF) of the two-tier heterogeneous networks without channel ...
We study the high-signal-to-noise-ratio capacity of generic multiple-input multiple-output (MIMO) Ra...
We consider a single-hop interference network with K transmitters and J receivers, all having M ante...
The degrees of freedom (DoF) of the 3-user multiple-input multiple-output (MIMO) interference channe...
The degrees of freedom (DoF) region of the fast-fading MIMO (multiple-input multiple-output) Gaussia...
We provide inner bound and outer bound for the total number of degrees of freedom of the K user mult...
We explore the available degrees of freedom (DoF) for the two user MIMO interference channel, and fi...
We consider a single hop interference network with K transmitters, each with an independent message ...
Abstract—We provide the characterization of the degrees of freedom (DOF) region for a 2-user fading ...
This paper gives the approximate capacity region of a two-user MIMO interference channel with limite...
This paper gives the approximate capacity region of a two-user MIMO interference channel with limite...
interference and cognitive radio channels are studied under the assumption of no channel state infor...
Abstract—While the outer-bound of sum degrees of freedom (DoF) of 3-user interference channel is kno...
Abstract — We provide achievability as well as converse results for the degrees of freedom region of...
Abstract — In this paper, we provide a lower and upper bound for the number of degrees of freedom (D...
We characterize the degrees of freedom (DoF) of the two-tier heterogeneous networks without channel ...
We study the high-signal-to-noise-ratio capacity of generic multiple-input multiple-output (MIMO) Ra...
We consider a single-hop interference network with K transmitters and J receivers, all having M ante...
The degrees of freedom (DoF) of the 3-user multiple-input multiple-output (MIMO) interference channe...
The degrees of freedom (DoF) region of the fast-fading MIMO (multiple-input multiple-output) Gaussia...
We provide inner bound and outer bound for the total number of degrees of freedom of the K user mult...
We explore the available degrees of freedom (DoF) for the two user MIMO interference channel, and fi...
We consider a single hop interference network with K transmitters, each with an independent message ...
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