Joint Activity Detection and Channel Estimation for IoT Networks: Phase Transition and Computation-Estimation Tradeoff

Abstract: Massive device connectivity is a crucial communication challenge for Internet of Things (IoT) networks, which consist of a large number of devices with sporadic traffic. In each coherence block, the serving base station needs to identify the active devices and estimate their channel state information for effective communication. By exploiting the sparsity pattern of data transmission, we develop a structured group sparsity estimation method to simultaneously detect the active devices and estimate the correspon… Show more

“…In this paper, we focus on sporadic communications [13,25], e.g., only a subset of all devices are active in each coherence block with probability ρ and α k = 1 denotes the active state of the k-th device, otherwise α k = 0. For the propose of IRS-related device activity detection and channel estimation, the k-th device will transmit a unique signature sequence…”

Intelligent Reflecting Surface for Massive Device Connectivity: Joint Activity Detection and Channel Estimation

“…In this paper, we focus on sporadic communications [13,25], e.g., only a subset of all devices are active in each coherence block with probability ρ and α k = 1 denotes the active state of the k-th device, otherwise α k = 0. For the propose of IRS-related device activity detection and channel estimation, the k-th device will transmit a unique signature sequence…”

Intelligent Reflecting Surface for Massive Device Connectivity: Joint Activity Detection and Channel Estimation

“…Conventionally, interference is considered as the most harmful factor limiting LUs' receiving performance. By leveraging the channel reciprocity and exploiting the characteristics of IoT communications, such as joint active devices detection and channel estimation, and sparsity pattern of data transmission, channel state information (CSI) acquisition can be efficient in IoT [8]. Hence, with CSI available at the transmitter, multi-user interference can be predicted and characterized prior to transmission.…”

Energy- and Cost-Efficient Physical Layer Security in the Era of IoT: The Role of Interference

“…However, the conventional multiple access protocols, e.g., ALOHA, which limit the number of access devices and require a high signalling overhead, are no longer really fit for the massive access systems [44,45]. To solve this problem, the grant-free random access protocol is widely applied in the massive access systems [46,47]. Specifically, each device is assigned with a unique pilot sequence for activity detection and channel estimation.…”

Physical layer security for massive access in cellular Internet of Things