Abstract
Ultra-reliable low latency communication (URLLC) is one of three primary use cases in the fifth-generation (5G) networks, and its research is still in its infancy due to its stringent and conflicting requirements in terms of extremely high reliability and low latency. To reduce latency, the channel blocklength for packet transmission is finite, which incurs transmission rate degradation and higher decoding error probability. In this case, conventional resource allocation based on Shannon capacity achieved with infinite blocklength codes is not optimal. Security is another critical issue in mission-critical internet of things (IoT) communications, and physical-layer security is a promising technique that can ensure the confidentiality for wireless communications as no additional channel uses are needed for the key exchange as in the conventional upper-layer cryptography method. This paper is the first work to study the resource allocation for a secure mission-critical IoT communication system with URLLC. Specifically, we adopt the security capacity formula under finite blocklength and consider two optimization problems: weighted throughput maximization problem and total transmit power minimization problem. Each optimization problem is non-convex and challenging to solve, and we develop efficient methods to solve each optimization problem. Simulation results confirm the fast convergence speed of our proposed algorithm and demonstrate the performance advantages over the existing benchmark algorithms.
Highlights
T HE fifth-generation (5G) networks are expected to support three main use cases: enhanced mobile broadband, massive machine type communication, and ultra-reliable low latency communication (URLLC) [1]
We studied a secure mission-critical internet of things (IoT) communication system under URLLC requirements, where the access point (AP) transmits safety-critical messages to the devices and there exists an eavesdropper that attempts to eavesdrop this critical message
We considered the weighted sum throughput (WST) maximization problem and the transmit power (TTP) minimization problem through joint bandwidth unit and power allocation
Summary
T HE fifth-generation (5G) networks are expected to support three main use cases: enhanced mobile broadband (eMBB), massive machine type communication (mMTC), and ultra-reliable low latency communication (URLLC) [1]. Significant advancement has been achieved in the last decade for the use case of eMBB characterized by high throughput and data rate. Some typical techniques include massive multiple-input multiple-output (MIMO) and mmWave. Manuscript received February 17, 2020; revised April 25, 2020 and May 29, 2020; accepted May 29, 2020. Date of publication June 3, 2020; date of current version September 16, 2020. The associate editor coordinating the review of this article and approving it for publication was D.
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