Abstract
Ultra-reliable and low-latency communication (URLLC) is one of three pillar applications defined in the fifth generation new radio (5G NR), and its research is still in its infancy due to the difficulties in guaranteeing extremely high reliability (say 10−9 packet loss probability) and low latency (say 1 ms) simultaneously. In URLLC, short packet transmission is adopted to reduce latency, such that conventional Shannon’s capacity formula is no longer applicable, and the achievable data rate in finite blocklength becomes a complex expression with respect to the decoding error probability and the blocklength. To provide URLLC service in a factory automation scenario, we consider that the central controller transmits different packets to a robot and an actuator, where the actuator is located far from the controller, and the robot can move between the controller and the actuator. In this scenario, we consider four fundamental downlink transmission schemes, including orthogonal multiple access (OMA), non-orthogonal multiple access (NOMA), relay-assisted, and cooperative NOMA (C-NOMA) schemes. For all these transmission schemes, we aim for jointly optimizing the blocklength and power allocation to minimize the decoding error probability of the actuator subject to the reliability requirement of the robot, the total energy constraints, as well as the latency constraints. We further develop low-complexity algorithms to address the optimization problems for each transmission scheme. For the general case with more than two devices, we also develop a low-complexity efficient algorithm for the OMA scheme. Our results show that the relay-assisted transmission significantly outperforms the OMA scheme, while the NOMA scheme performs well when the blocklength is very limited. We further show that the relay-assisted transmission has superior performance over the C-NOMA scheme due to larger feasible region of the former scheme.
Highlights
T HE fifth-generation (5G) networks are envisaged to support three pillar use cases: enhanced mobile broadband, massive machine type communication, and Manuscript received October 31, 2018; revised April 18, 2019 and September 23, 2019; accepted November 28, 2019
We assume that the controller, the robot and the actuator are located on the same line, and the robot is moving from the controller to the actuator, and the robot is served as the relay to help the transmission of the actuator
The small-scale fading channel is taken into consideration in the channel gain, and we study the network availability performance, which is defined as the ratio of the number of channel generations, where the decoding error probability achieved by both devices is no larger than 10−9, to the total number of channel generations [2]
Summary
T HE fifth-generation (5G) networks are envisaged to support three pillar use cases: enhanced mobile broadband (eMBB), massive machine type communication (mMTC), and Manuscript received October 31, 2018; revised April 18, 2019 and September 23, 2019; accepted November 28, 2019. This article was presented in part at the IEEE ICC 2019. Color versions of one or more of the figures in this article are available online at http://ieeexplore.ieee.org. Extensive research has focused on eMBB and mMTC, but the research on mission-critical IoT is still in its infancy [2]–[6]. In Industrial 4.0 [11], wired connection will be replaced by wireless transmission to enhance the flexibility and reduce the infrastructure cost. This change imposes challenging requirements on the wireless transmission in terms of latency and reliability [12]. For mission-critical tasks in FA, the transmission duration is expected to be lower than 100 μs to allow processing delays during queuing, scheduling, backhaul transmission, and propagation [13], while guaranteeing the packet error probability of 10−9
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