Runtime Precoding: Enabling Multipoint Transmission in LTE-Advanced System-Level Simulations

Taranetz, Martin; Blazek, Thomas; Kropfreiter, Thomas; Müller, Martin Klaus; Schwarz, Štefan; Rupp, Markus

doi:10.1109/access.2015.2437903

Cited by 66 publications

(26 citation statements)

References 24 publications

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“…9a, it is observed that the results scale approximately linear with the number K of UEs and with the simulation length N TTI . Such behavior was already observed in [22] together with a more detailed description of its origins. In this paper, our main interest is on the impact of the elevation direction and the application of the 3GPP 3D channel model for interfering channels on the simulation run time.…”

Section: Simulation Run Timesmentioning

confidence: 83%

“…We now extend this approach by also taking into account the interfering links. We integrate our code into the Vienna LTEA Downlink System Level Simulator (current version v1.8r1375) [22]. The simulator is implemented in object-oriented MAT-LAB and is made openly available for download under an academic, non-commercial use license.…”

Section: Simulation Run Times and Throughput Performance Evaluationmentioning

confidence: 99%

“…On link level, channel realizations are typically calculated per OFDM symbol and LTE-A subcarrier [21]. On system level, they are commonly generated per physical resource block (RB) and transmission time interval (TTI) [22].…”

Section: Implementation In System-levelmentioning

confidence: 99%

“…6 and, thus, serves as a representative example. Its centerpiece is the link abstraction model that specifies the interaction between link-and system level simulations [1,22]. This structure is expected to persist in simulation tools for the fifth generation of mobile cellular networks (5G) [24].…”

Section: Simulation Run Times and Throughput Performance Evaluationmentioning

confidence: 99%

See 3 more Smart Citations

3GPP 3D MIMO channel model: a holistic implementation guideline for open source simulation tools

Ademaj

Taranetz

Rupp

2016

J Wireless Com Network

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Massive MIMO and 3D beamforming have been identified as key technologies for future mobile cellular networks. Their investigation requires channel models that consider not only the azimuth-but also the elevation direction. Recently, the 3rd Generation Partnership Project (3GPP) has released a new 3D spatial channel model. It supports planar antenna arrays and enables to scrutinize concepts such as elevation beamforming and full dimension MIMO. A particular challenge is the practical implementation of the model. Dealing with enormous computational complexity requires to design a highly efficient approach. This paper provides a guideline for the practical implementation of the 3GPP 3D model into existing link-and system-level simulation tools. Considering the complexity of the model itself, our main focus is on computational efficiency. We present simulation examples using the proposed procedure with the Vienna LTE-A Downlink System Level Simulator. We measure simulation run times with respect to various network parameters. Our results allow to quantify the increase in complexity, when accounting for the elevation dimension. Moreover, they exhibit general trends when considering a large number of antenna elements per antenna array. We also draw a comparison with the WINNER channel model, which represents the most closely related channel model in 2D.

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Section: Simulation Run Timesmentioning

confidence: 83%

Section: Simulation Run Times and Throughput Performance Evaluationmentioning

confidence: 99%

Section: Implementation In System-levelmentioning

confidence: 99%

Section: Simulation Run Times and Throughput Performance Evaluationmentioning

confidence: 99%

See 2 more Smart Citations

3GPP 3D MIMO channel model: a holistic implementation guideline for open source simulation tools

Ademaj

Taranetz

Rupp

2016

J Wireless Com Network

Self Cite

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“…An algorithm was developed in Reference [8] in order to optimise the number of RRUs deployed in a network using game theory. Multipoint transmission coordination of distributed RRUs has been investigated in References [9,10]. While the first investigation on using remote antennas in the mmWave band was introduced in Reference [11], where the author has demonstrated the importance of remote antennas on minimising the shadow fading of wireless networks in the Local Multipoint Distribution Service (LMDS) band.…”

Section: Introductionmentioning

confidence: 99%

Improved Capacity and Fairness of Massive Machine Type Communications in Millimetre Wave 5G Network

Al-Falahy

Alani

2018

Computers

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Abstract:In the Fifth Generation (5G) wireless standard, the Internet of Things (IoT) will interconnect billions of Machine Type Communications (MTC) devices. Fixed and mobile wearable devices and sensors are expected to contribute to the majority of IoT traffic. MTC device mobility has been considered with three speeds, namely zero (fixed) and medium and high speeds of 30 and 100 kmph. Different values for device mobility are used to simulate the impact of device mobility on MTC traffic. This work demonstrates the gain of using distributed antennas on MTC traffic in terms of spectral efficiency and fairness among MTC devices, which affects the number of devices that can be successfully connected. The mutual use of Distributed Base Stations (DBS) with Remote Radio Units (RRU) and the adoption of the millimetre wave band, particularly in the 26 GHz range, have been considered the key enabling technologies for addressing MTC traffic growth. An algorithm has been set to schedule this type of traffic and to show whether MTC devices completed their traffic upload or failed to reach the margin. The gains of the new architecture have been demonstrated in terms of spectral efficiency, data throughput and the fairness index.

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Impact of multiple system diversity on throughput in heterogeneous cellular networks

Wang

2018

Int J Communication

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As different generations of mobile communication systems are installed in the same area, a mobile terminal (MT) can utilize the multisystem diversity (MSD) by accessing the system providing the highest signal-to-interference-and-noise ratio (SINR). However, it is difficult to practically calculate the capacity gain obtained from the MSD environment by using conventional capacity analysis methodologies because each mobile communication system operates in different frequency and channel environments. In this paper, we propose a Poisson-point process (PPP)-based hybrid approach in order to analyze the MSD capacity gain. In the hybrid approach, the SINR interval probability is first derived considering the MSD order. Since SINR intervals are mapped to CQI-MCS table values used in real-world cellular systems, we can calculate a substantially valid system capacity in the MSD environment. In our result, the reliability of the proposed analysis tool is verified by confirming that the existing capacity analysis results can be benchmarked. Based on the reliability, the MSD capacity gain is quantitatively analyzed when heterogeneous cellular systems coexist and interact. KEYWORDS heterogeneous cellular networks, PPP analysisRecently, standardization of the fifth generation (5G) mobile communication system is actively underway. 1,2 The 5G system operates in the tens of GHz frequency band and will operate simultaneously with the fourth generation (4G) mobile communication system to provide stable service coverage. The 5G system can provide signal transmissions in multiple subbands. 3,4 In such a mobile communication environment, a mobile terminal (MT) has an opportunity to access multiple systems at a location. Assuming 5G base stations (BS) installed in different locations from the 4G system, an MT can receive signals with different signal-to-interference-and-noise ratio (SINR) values from the 4G and 5G systems. If 5G BSs are operating in different subbands, an MT might also experience different SINR values at each subband. In such a wireless communication environment, an MT can newly pursue multisystem diversity (MSD) where the MT can select the best system or subband which provides the maximum SINR.In the MSD environment, the statistical characteristics of the received SINR must be different from the conventional wireless communication environment. In order to analyze the system capacity in the MSD environment, a probability density function (pdf) of the SINR should be first derived. There have been some theoretical researches in order to derive Int J Commun Syst. 2018;31:e3828.wileyonlinelibrary.com/journal/dac

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Runtime Precoding: Enabling Multipoint Transmission in LTE-Advanced System-Level Simulations

Cited by 66 publications

References 24 publications

3GPP 3D MIMO channel model: a holistic implementation guideline for open source simulation tools

3GPP 3D MIMO channel model: a holistic implementation guideline for open source simulation tools

Improved Capacity and Fairness of Massive Machine Type Communications in Millimetre Wave 5G Network

Impact of multiple system diversity on throughput in heterogeneous cellular networks

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