Massive Random Access with Common Alarm Messages

The established view on massive IoT access is that the IoT devices are activated randomly and independently. This is a basic premise also in the recent information-theoretic treatment of massive access by Polyanskiy. In a number of practical scenarios, the information from IoT devices in a given geographical area is inherently correlated due to a commonly observed physical phenomenon. We introduce a model for massive access that accounts for correlation both in device activation and in the message content. To this end, we introduce common alarm messages for all devices. A physical phenomenon can trigger an alarm causing a subset of devices to transmit the same message at the same time. We develop a new error probability model that includes false positive errors, resulting from decoding a non-transmitted codeword. The results show that the correlation allows for high reliability at the expense of spectral efficiency. This reflects the intuitive trade-off: an access from a massive number can be ultra-reliable only if the information across the devices is correlated.Comment: Extended version of conference submissio

Hybrid MIMO: a new transmission method for simultaneously achieving spatial multiplexing and diversity gains in MIMO systems

Multiple input multiple output (MIMO) technology has evolved over the past few years into a technology with great potential to drive the direction of future wireless communications. MIMO technology has become a solid reality when massive MIMO systems (MIMO with large number of antennas and transceivers) were commercially deployed in several countries across the world in the recent past. Moreover, MIMO has been integrated into state-of-the-art paradigms such as fifth-generation (5G) networks as one of the main enabling technologies. MIMO possesses many attractive and highly desirable properties such as spatial multiplexing, diversity gains, and adaptive beamforming gains that leads to high data rates, enhanced reliability, and other enhancements. Nevertheless, beyond 5G technologies demand wireless communication systems with, among other properties, immensely higher data rates and better reliability simultaneously at the same time. In this work, a new, novel MIMO technique for simultaneously achieving multiplexing and diversity gains as well as completely eliminating any processing at the MIMO receiver, leading to advantages such as low complexity and low power consumption, is proposed. The proposed technique employs the design of interference-canceling matrices, which are calculated from the channels between the transceiver antennas, where the matrices are employed at the base station to help achieve multiplexing and diversity gains simultaneously. The novelty and efficiency of the introduced paradigm is demonstrated via mathematical models and validated by Monte Carlo simulations. Results indicate that the proposed system outperforms conventional MIMO models.No sponso

increasing efficiency of resource allocation for d2d communication in nb iot context

Abstract Internet of things (IoT) and device to device (D2D) communications are among the novel promising technologies in the current releases of 4G and they will play a fundamental role in the next generation 5G as well. In this paper, it is investigated the impact of allocation strategies that take into account the mutual interference in D2D Narrow-Band IoT terminals and cellular terminals transmitting in the same resource block. In a multi-cellular downlink context, the proposed approach and the analysis can serve also as an efficient criterion for selecting the target SINR, useful for managing the power control in the uplink. The rate improvement, measured with the proposed approach, is between 10% and 15% w.r.t. conventional techniques

Inductorless LNA and Harmonic-rejection Mixer for Wideband Direct-conversion Receiver

In this master thesis, combinations of noise-canceling LNA and harmonic-rejection mixers are investigated and compared to find an optimal inductorless receiver front-end for low-band (600-960MHz) FDD LTE-A network. The work was carried out in a modem development project at Ericsson Modems, Lund. Three receiver versions with different harmonic rejection techniques are compared in terms of noise figure (NF) and power consumption and the receiver with 6 LO phases is selected for optimization. The LNA combines noise cancellation for matching stage and nonlinearity cancellation for output stages so both low noise figure and high linearity are achieved. The final circuit show great potential for FDD LTE-A system with support up to 3 aggregated carriers for higher bandwidth. Low NF at 1.62 dB after the LNA and 1.75 dB after the mixer are observed from 0.4-1GHz. The LNA IIP2 is above 12 dBm and robust with process and temperature. Gain switching with possible reduction of 6 and 12 dB is integrated and the LNA linearity is not significantly suffered by low gain. Input return loss (S11) is better than -12dB regardless of gain, number of carriers and temperature (-30 – 110°C). Inductorless operation saves a lot of chip area and avoid dead package area, which then save cost and make the solution competitive.This master’s thesis done at Ericsson Modem aimed to investigate an inductorless receiver front-end for low-band LTE-A user terminals. The circuit combined noise-canceling technique and push-pull stage for LNA and harmonic-rejection technique for mixer, so three main issues of inductorless operation are solved. The issues include LNA noise and linearity, and noise folding effect caused by 3rd harmonics of LO signals