We propose inhomogeneous random K-out graphs $\mathbb{H}(n; \pmb��, \pmb{K}_n)$, where each of the $n$ nodes is assigned to one of $r$ classes independently with a probability distribution $\pmb�� = \{��_1, \ldots, ��_r\}$. In particular, each node is classified as class-$i$ with probability $��_i>0$, independently. Each class-$i$ node selects $K_{i,n}$ distinct nodes uniformly at random from among all other nodes. A pair of nodes are adjacent in $\mathbb{H}(n; \pmb��, \pmb{K}_n)$ if at least one selects the other. Without loss of generality, we assume that $K_{1,n} \leq K_{2,n} \leq \ldots \leq K_{r,n}$. Earlier results on homogeneous random K-out graphs $\mathbb{H}(n; K_n)$, where all nodes select the same number $K$ of other nodes, reveal that $\mathbb{H}(n; K_n)$ is connected with high probability (whp) if $K_n \geq 2$ which implies that $\mathbb{H}(n; \pmb��, \pmb{K}_n)$ is connected whp if $K_{1,n} \geq 2$. In this paper, we investigate the connectivity of inhomogeneous random K-out graphs $\mathbb{H}(n; \pmb��, \pmb{K}_n)$ for the special case when $K_{1,n}=1$, i.e., when each class-$1$ node selects only one other node. We show that $\mathbb{H}\left(n;\pmb��,\pmb{K}_n\right)$ is connected whp if $K_{r,n}$ is chosen such that $\lim_{n \to \infty} K_{r,n} = \infty$. However, any bounded choice of the sequence $K_{r,n}$ gives a positive probability of $\mathbb{H}\left(n;\pmb��,\pmb{K}_n\right)$ being not connected. Simulation results are provided to validate our results in the finite node regime.

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