In this dissertation, the cross-layer design on the coordinated transmission and retransmission protocol and the performance analysis are provided in mobile small cell networks (SCNs). Firstly we design three opportunistic multipoint relaying mechanisms with using opportunistic distributed space-time coding (ODSTC) for coordinated Automatic-Repeat-reQuest (ARQ) according to the protocol complexities for temporal and spatial diversity exploration in retransmissions. Based on an analytic approach of outage analysis, the effectiveness of the proposed ARQ protocols is studied from the perspectives of diversity and throughput performance, and the relay efficiency is investigated from the viewpoint of signal quality improvement per active relay. In spite of a great amount of potential helpers (relays) in SCNs, the numerical results show that opportunistically choosing 2 active relays for ODSTC in at most two rounds of retransmissions is good enough to yield a significant throughput improvement. Based on this inspiring result, we continue to exploit and study the advantage of the coordinated ARQ protocols from a cross-layer perspective. The proposed ARQ protocols are implemented under the frame structure of the long term evolution advanced (LTE-A) time division duplex (TDD) system, and a simplified analytical model is provided to study the mobility impact on downlink (DL) throughput. Subject to the relays’ queue stability and energy constraint, the data rate of the base station and the active relay(s) are selected to maximize the DL throughput under different mobility conditions. The numerical and simulation results show that enabling relay overhearing and opportunistically reselecting relays at every round of retransmission can significantly improve the throughput when the users are in the indoor environment or moving at a walking speed. If the users are traveling at a medium vehicular speed (~30km/h), reselection only is good enough to provide a throughput gain. To the users who travel at a high speed (>80km/h), a more realistic and efficient method is to use all the candidate relays to forward signals with distributed space-time coding (DSTC) together.