在裝置間通訊傳輸中，要成功的在蜂巢式網路使用者以及裝置間通訊使用者之間成功應用要先解決致命的雙重干擾問題。重所皆知的史塔貝克賽局理論經過良好的設計可以減緩這種雙重干擾的影響。然而大部分的賽局理論缺少了對蜂巢式網路使用者的保護。也就是說在這篇論文中，我們把性能導向保護限制的區域融合了史塔貝克賽局理論來對蜂巢式網路使用者進行保護。此外為了要完整的運用蜂巢式網路使用者的資源，傳統的性能導向方案也被運用在提升裝置間使用者的性能。藉由結合這三種技術，我們提出了符合公平保護原則的性能導向資源分類方案。通過模擬結果，可以證明整個系統效能的優異表現。

In the device-to-device (D2D) communications, the mutual interference between the cellular users (CUs) and D2D pairs is fatal to its successful application. It is well
known that a well designed Stackelberg game approach can alleviate the impact of the mutual interference. However, in the most game-based approaches, a stronger protection mechanism for CUs is lacked. Thus, in this thesis, we incorporate the capacity-oriented restricted region (CORE) into the conventional Stackelberg game approach such that the CUs can be well protected. Moreover, to fully utilize the CUs' resource, the conventional capacity oriented resource allocation (CORAL) algorithm is applied to boost the D2D pair's capacity. By combining these three techniques, we propose the fairness-and-safety capacity oriented resource allocation (FAST CORAL)
scheme. Via the simulation results, the superior performance of the overall system capacity is demonstrated.

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