Design Documentation

Overview

An overview of the LTE-EPC simulation model is depicted in the figure Overview of the LTE-EPC simulation model. There are two main components:

  • the LTE Model. This model includes the LTE Radio Protocol stack (RRC, PDCP, RLC, MAC, PHY). These entities reside entirely within the UE and the eNB nodes.

  • the EPC Model. This model includes core network interfaces, protocols and entities. These entities and protocols reside within the SGW, PGW and MME nodes, and partially within the eNB nodes.

_images/epc-topology-with-split.png

Overview of the LTE-EPC simulation model

Design Criteria

LTE Model

The LTE model has been designed to support the evaluation of the following aspects of LTE systems:

  • Radio Resource Management

  • QoS-aware Packet Scheduling

  • Inter-cell Interference Coordination

  • Dynamic Spectrum Access

In order to model LTE systems to a level of detail that is sufficient to allow a correct evaluation of the above mentioned aspects, the following requirements have been considered:

  1. At the radio level, the granularity of the model should be at least that of the Resource Block (RB). In fact, this is the fundamental unit being used for resource allocation. Without this minimum level of granularity, it is not possible to model accurately packet scheduling and inter-cell-interference. The reason is that, since packet scheduling is done on a per-RB basis, an eNB might transmit on a subset only of all the available RBs, hence interfering with other eNBs only on those RBs where it is transmitting. Note that this requirement rules out the adoption of a system level simulation approach, which evaluates resource allocation only at the granularity of call/bearer establishment.

  2. The simulator should scale up to tens of eNBs and hundreds of User Equipment (UEs). This rules out the use of a link level simulator, i.e., a simulator whose radio interface is modeled with a granularity up to the symbol level. This is because to have a symbol level model it is necessary to implement all the PHY layer signal processing, whose huge computational complexity severely limits simulation. In fact, link-level simulators are normally limited to a single eNB and one or a few UEs.

  3. It should be possible within the simulation to configure different cells so that they use different carrier frequencies and system bandwidths. The bandwidth used by different cells should be allowed to overlap, in order to support dynamic spectrum licensing solutions such as those described in [Ofcom2600MHz] and [RealWireless]. The calculation of interference should handle appropriately this case.

  4. To be more representative of the LTE standard, as well as to be as close as possible to real-world implementations, the simulator should support the MAC Scheduler API published by the FemtoForum [FFAPI]. This interface is expected to be used by femtocell manufacturers for the implementation of scheduling and Radio Resource Management (RRM) algorithms. By introducing support for this interface in the simulator, we make it possible for LTE equipment vendors and operators to test in a simulative environment exactly the same algorithms that would be deployed in a real system.

  5. The LTE simulation model should contain its own implementation of the API defined in [FFAPI]. Neither binary nor data structure compatibility with vendor-specific implementations of the same interface are expected; hence, a compatibility layer should be interposed whenever a vendor-specific MAC scheduler is to be used with the simulator. This requirement is necessary to allow the simulator to be independent from vendor-specific implementations of this interface specification. We note that [FFAPI] is a logical specification only, and its implementation (e.g., translation to some specific programming language) is left to the vendors.

  6. The model is to be used to simulate the transmission of IP packets by the upper layers. With this respect, it shall be considered that in LTE the Scheduling and Radio Resource Management do not work with IP packets directly, but rather with RLC PDUs, which are obtained by segmentation and concatenation of IP packets done by the RLC entities. Hence, these functionalities of the RLC layer should be modeled accurately.

EPC Model

The main objective of the EPC model is to provides means for the simulation of end-to-end IP connectivity over the LTE model. To this aim, it supports for the interconnection of multiple UEs to the Internet, via a radio access network of multiple eNBs connected to the core network, as shown in Figure Overview of the LTE-EPC simulation model.

The following design choices have been made for the EPC model:

  1. The Packet Data Network (PDN) type supported is both IPv4 and IPv6. In other words, the end-to-end connections between the UEs and the remote hosts can be IPv4 and IPv6. However, the networks between the core network elements (MME, SGWs and PGWs) are IPv4-only.

  2. The SGW and PGW functional entities are implemented in different nodes, which are hence referred to as the SGW node and PGW node, respectively.

  3. The MME functional entities is implemented as a network node, which is hence referred to as the MME node.

  4. The scenarios with inter-SGW mobility are not of interest. But several SGW nodes may be present in simulations scenarios.

  5. A requirement for the EPC model is that it can be used to simulate the end-to-end performance of realistic applications. Hence, it should be possible to use with the EPC model any regular ns-3 application working on top of TCP or UDP.

  6. Another requirement is the possibility of simulating network topologies with the presence of multiple eNBs, some of which might be equipped with a backhaul connection with limited capabilities. In order to simulate such scenarios, the user data plane protocols being used between the eNBs and the SGW should be modeled accurately.

  7. It should be possible for a single UE to use different applications with different QoS profiles. Hence, multiple EPS bearers should be supported for each UE. This includes the necessary classification of TCP/UDP traffic over IP done at the UE in the uplink and at the PGW in the downlink.

  8. The initial focus of the EPC model is mainly on the EPC data plane. The accurate modeling of the EPC control plane is, for the time being, not a requirement; however, the necessary control plane interactions among the different network nodes of the core network are realized by implementing control protocols/messages among them. Direct interaction among the different simulation objects via the provided helper objects should be avoided as much as possible.

  9. The focus of the EPC model is on simulations of active users in ECM connected mode. Hence, all the functionality that is only relevant for ECM idle mode (in particular, tracking area update and paging) are not modeled at all.

  10. The model should allow the possibility to perform an X2-based handover between two eNBs.

Architecture

LTE Model

UE architecture

The architecture of the LTE radio protocol stack model of the UE is represented in the figures LTE radio protocol stack architecture for the UE on the data plane and LTE radio protocol stack architecture for the UE on the control plane which highlight respectively the data plane and the control plane.

_images/lte-arch-ue-data.png

LTE radio protocol stack architecture for the UE on the data plane

_images/lte-arch-ue-ctrl.png

LTE radio protocol stack architecture for the UE on the control plane

The architecture of the PHY/channel model of the UE is represented in figure PHY and channel model architecture for the UE.

_images/lte-ue-phy.png

PHY and channel model architecture for the UE

eNB architecture

The architecture of the LTE radio protocol stack model of the eNB is represented in the figures LTE radio protocol stack architecture for the eNB on the data plane and LTE radio protocol stack architecture for the eNB on the control plane which highlight respectively the data plane and the control plane.

_images/lte-arch-enb-data.png

LTE radio protocol stack architecture for the eNB on the data plane

_images/lte-arch-enb-ctrl.png

LTE radio protocol stack architecture for the eNB on the control plane

The architecture of the PHY/channel model of the eNB is represented in figure PHY and channel model architecture for the eNB.

_images/lte-enb-phy.png

PHY and channel model architecture for the eNB

EPC Model

EPC data plane

In Figure LTE-EPC data plane protocol stack, we represent the end-to-end LTE-EPC data plane protocol stack as it is modeled in the simulator. The figure shows all nodes in the data path, i.e. UE, eNB, SGW, PGW and a remote host in the Internet. All protocol stacks (S5 protocol stack, S1-U protocol stack and the LTE radio protocol stack) specified by 3GPP are present.

_images/lte-epc-e2e-data-protocol-stack-with-split.png

LTE-EPC data plane protocol stack

EPC control plane

The architecture of the implementation of the control plane model is shown in figure LTE-EPC control plane protocol stack. The control interfaces that are modeled explicitly are the S1-MME, the S11, and the S5 interfaces. The X2 interface is also modeled explicitly and it is described in more detail in section X2

The S1-MME, the S11 and the S5 interfaces are modeled using procotol data units sent over its respective links. These interfaces use the SCTP protocol as transport protocol but currently, the SCTP protocol is not modeled in the ns-3 simulator, so the UDP protocol is used instead of the SCTP protocol.

_images/lte-epc-e2e-control-protocol-stack-with-split.png

LTE-EPC control plane protocol stack

Channel and Propagation

For channel modeling purposes, the LTE module uses the SpectrumChannel interface provided by the spectrum module. At the time of this writing, two implementations of such interface are available: SingleModelSpectrumChannel and MultiModelSpectrumChannel, and the LTE module requires the use of the MultiModelSpectrumChannel in order to work properly. This is because of the need to support different frequency and bandwidth configurations. All the propagation models supported by MultiModelSpectrumChannel can be used within the LTE module.

Use of the Buildings model with LTE

The recommended propagation model to be used with the LTE module is the one provided by the Buildings module, which was in fact designed specifically with LTE (though it can be used with other wireless technologies as well). Please refer to the documentation of the Buildings module for generic information on the propagation model it provides.

In this section we will highlight some considerations that specifically apply when the Buildings module is used together with the LTE module.

The naming convention used in the following will be:

  • User equipment: UE

  • Macro Base Station: MBS

  • Small cell Base Station (e.g., pico/femtocell): SC

The LTE module considers FDD only, and implements downlink and uplink propagation separately. As a consequence, the following pathloss computations are performed

  • MBS <-> UE (indoor and outdoor)

  • SC (indoor and outdoor) <-> UE (indoor and outdoor)

The LTE model does not provide the following pathloss computations:

  • UE <-> UE

  • MBS <-> MBS

  • MBS <-> SC

  • SC <-> SC

The Buildings model does not know the actual type of the node; i.e., it is not aware of whether a transmitter node is a UE, a MBS, or a SC. Rather, the Buildings model only cares about the position of the node: whether it is indoor and outdoor, and what is its z-axis respect to the rooftop level. As a consequence, for an eNB node that is placed outdoor and at a z-coordinate above the rooftop level, the propagation models typical of MBS will be used by the Buildings module. Conversely, for an eNB that is placed outdoor but below the rooftop, or indoor, the propagation models typical of pico and femtocells will be used.

For communications involving at least one indoor node, the corresponding wall penetration losses will be calculated by the Buildings model. This covers the following use cases:

  • MBS <-> indoor UE

  • outdoor SC <-> indoor UE

  • indoor SC <-> indoor UE

  • indoor SC <-> outdoor UE

Please refer to the documentation of the Buildings module for details on the actual models used in each case.

Fading Model

The LTE module includes a trace-based fading model derived from the one developed during the GSoC 2010 [Piro2011]. The main characteristic of this model is the fact that the fading evaluation during simulation run-time is based on per-calculated traces. This is done to limit the computational complexity of the simulator. On the other hand, it needs huge structures for storing the traces; therefore, a trade-off between the number of possible parameters and the memory occupancy has to be found. The most important ones are:

  • users’ speed: relative speed between users (affects the Doppler frequency, which in turns affects the time-variance property of the fading)

  • number of taps (and relative power): number of multiple paths considered, which affects the frequency property of the fading.

  • time granularity of the trace: sampling time of the trace.

  • frequency granularity of the trace: number of values in frequency to be evaluated.

  • length of trace: ideally large as the simulation time, might be reduced by windowing mechanism.

  • number of users: number of independent traces to be used (ideally one trace per user).

With respect to the mathematical channel propagation model, we suggest the one provided by the rayleighchan function of Matlab, since it provides a well accepted channel modelization both in time and frequency domain. For more information, the reader is referred to [mathworks].

The simulator provides a matlab script (src/lte/model/fading-traces/fading-trace-generator.m) for generating traces based on the format used by the simulator. In detail, the channel object created with the rayleighchan function is used for filtering a discrete-time impulse signal in order to obtain the channel impulse response. The filtering is repeated for different TTI, thus yielding subsequent time-correlated channel responses (one per TTI). The channel response is then processed with the pwelch function for obtaining its power spectral density values, which are then saved in a file with the proper format compatible with the simulator model.

Since the number of variable it is pretty high, generate traces considering all of them might produce a high number of traces of huge size. On this matter, we considered the following assumptions of the parameters based on the 3GPP fading propagation conditions (see Annex B.2 of [TS36104]):

  • users’ speed: typically only a few discrete values are considered, i.e.:

    • 0 and 3 kmph for pedestrian scenarios

    • 30 and 60 kmph for vehicular scenarios

    • 0, 3, 30 and 60 for urban scenarios

  • channel taps: only a limited number of sets of channel taps are normally considered, for example three models are mentioned in Annex B.2 of [TS36104].

  • time granularity: we need one fading value per TTI, i.e., every 1 ms (as this is the granularity in time of the ns-3 LTE PHY model).

  • frequency granularity: we need one fading value per RB (which is the frequency granularity of the spectrum model used by the ns-3 LTE model).

  • length of the trace: the simulator includes the windowing mechanism implemented during the GSoC 2011, which consists of picking up a window of the trace each window length in a random fashion.

  • per-user fading process: users share the same fading trace, but for each user a different starting point in the trace is randomly picked up. This choice was made to avoid the need to provide one fading trace per user.

According to the parameters we considered, the following formula express in detail the total size S_{traces} of the fading traces:

S_{traces} = S_{sample} \times N_{RB} \times \frac{T_{trace}}{T_{sample}} \times N_{scenarios} \mbox{ [bytes]}

where S_{sample} is the size in bytes of the sample (e.g., 8 in case of double precision, 4 in case of float precision), N_{RB} is the number of RB or set of RBs to be considered, T_{trace} is the total length of the trace, T_{sample} is the time resolution of the trace (1 ms), and N_{scenarios} is the number of fading scenarios that are desired (i.e., combinations of different sets of channel taps and user speed values). We provide traces for 3 different scenarios one for each taps configuration defined in Annex B.2 of [TS36104]:

  • Pedestrian: with nodes’ speed of 3 kmph.

  • Vehicular: with nodes’ speed of 60 kmph.

  • Urban: with nodes’ speed of 3 kmph.

hence N_{scenarios} = 3. All traces have T_{trace} = 10 s and RB_{NUM} = 100. This results in a total 24 MB bytes of traces.

Antennas

Being based on the SpectrumPhy, the LTE PHY model supports antenna modeling via the ns-3 AntennaModel class. Hence, any model based on this class can be associated with any eNB or UE instance. For instance, the use of the CosineAntennaModel associated with an eNB device allows to model one sector of a macro base station. By default, the IsotropicAntennaModel is used for both eNBs and UEs.

PHY

Overview

The physical layer model provided in this LTE simulator is based on the one described in [Piro2011], with the following modifications. The model now includes the inter cell interference calculation and the simulation of uplink traffic, including both packet transmission and CQI generation.

Subframe Structure

The subframe is divided into control and data part as described in Figure LTE subframe division..

_images/lte-subframe-structure.png

LTE subframe division.

Considering the granularity of the simulator based on RB, the control and the reference signaling have to be consequently modeled considering this constraint. According to the standard [TS36211], the downlink control frame starts at the beginning of each subframe and lasts up to three symbols across the whole system bandwidth, where the actual duration is provided by the Physical Control Format Indicator Channel (PCFICH). The information on the allocation are then mapped in the remaining resource up to the duration defined by the PCFICH, in the so called Physical Downlink Control Channel (PDCCH). A PDCCH transports a single message called Downlink Control Information (DCI) coming from the MAC layer, where the scheduler indicates the resource allocation for a specific user. The PCFICH and PDCCH are modeled with the transmission of the control frame of a fixed duration of 3/14 of milliseconds spanning in the whole available bandwidth, since the scheduler does not estimate the size of the control region. This implies that a single transmission block models the entire control frame with a fixed power (i.e., the one used for the PDSCH) across all the available RBs. According to this feature, this transmission represents also a valuable support for the Reference Signal (RS). This allows of having every TTI an evaluation of the interference scenario since all the eNB are transmitting (simultaneously) the control frame over the respective available bandwidths. We note that, the model does not include the power boosting since it does not reflect any improvement in the implemented model of the channel estimation.

The Sounding Reference Signal (SRS) is modeled similar to the downlink control frame. The SRS is periodically placed in the last symbol of the subframe in the whole system bandwidth. The RRC module already includes an algorithm for dynamically assigning the periodicity as function of the actual number of UEs attached to a eNB according to the UE-specific procedure (see Section 8.2 of [TS36213]).

MAC to Channel delay

To model the latency of real MAC and PHY implementations, the PHY model simulates a MAC-to-channel delay in multiples of TTIs (1ms). The transmission of both data and control packets are delayed by this amount.

CQI feedback

The generation of CQI feedback is done accordingly to what specified in [FFAPI]. In detail, we considered the generation of periodic wideband CQI (i.e., a single value of channel state that is deemed representative of all RBs in use) and inband CQIs (i.e., a set of value representing the channel state for each RB).

The CQI index to be reported is obtained by first obtaining a SINR measurement and then passing this SINR measurement to the Adaptive Modulation and Coding module which will map it to the CQI index.

In downlink, the SINR used to generate CQI feedback can be calculated in two different ways:

  1. Ctrl method: SINR is calculated combining the signal power from the reference signals (which in the simulation is equivalent to the PDCCH) and the interference power from the PDCCH. This approach results in considering any neighboring eNB as an interferer, regardless of whether this eNB is actually performing any PDSCH transmission, and regardless of the power and RBs used for eventual interfering PDSCH transmissions.

  2. Mixed method: SINR is calculated combining the signal power from the reference signals (which in the simulation is equivalent to the PDCCH) and the interference power from the PDSCH. This approach results in considering as interferers only those neighboring eNBs that are actively transmitting data on the PDSCH, and allows to generate inband CQIs that account for different amounts of interference on different RBs according to the actual interference level. In the case that no PDSCH transmission is performed by any eNB, this method consider that interference is zero, i.e., the SINR will be calculated as the ratio of signal to noise only.

To switch between this two CQI generation approaches, LteHelper::UsePdschForCqiGeneration needs to be configured: false for first approach and true for second approach (true is default value):

Config::SetDefault ("ns3::LteHelper::UsePdschForCqiGeneration", BooleanValue (true));

In uplink, two types of CQIs are implemented:

  • SRS based, periodically sent by the UEs.

  • PUSCH based, calculated from the actual transmitted data.

The scheduler interface include an attribute system called UlCqiFilter for managing the filtering of the CQIs according to their nature, in detail:

  • SRS_UL_CQI for storing only SRS based CQIs.

  • PUSCH_UL_CQI for storing only PUSCH based CQIs.

It has to be noted that, the FfMacScheduler provides only the interface and it is matter of the actual scheduler implementation to include the code for managing these attributes (see scheduler related section for more information on this matter).

Interference Model

The PHY model is based on the well-known Gaussian interference models, according to which the powers of interfering signals (in linear units) are summed up together to determine the overall interference power.

The sequence diagram of Figure Sequence diagram of the PHY interference calculation procedure shows how interfering signals are processed to calculate the SINR, and how SINR is then used for the generation of CQI feedback.

_images/lte-phy-interference.png

Sequence diagram of the PHY interference calculation procedure

LTE Spectrum Model

The usage of the radio spectrum by eNBs and UEs in LTE is described in [TS36101]. In the simulator, radio spectrum usage is modeled as follows. Let f_c denote the LTE Absolute Radio Frequency Channel Number, which identifies the carrier frequency on a 100 kHz raster; furthermore, let B be the Transmission Bandwidth Configuration in number of Resource Blocks. For every pair (f_c,B) used in the simulation we define a corresponding SpectrumModel using the functionality provided by the Spectrum Module . model using the Spectrum framework described in [Baldo2009]. f_c and B can be configured for every eNB instantiated in the simulation; hence, each eNB can use a different spectrum model. Every UE will automatically use the spectrum model of the eNB it is attached to. Using the MultiModelSpectrumChannel described in [Baldo2009], the interference among eNBs that use different spectrum models is properly accounted for. This allows to simulate dynamic spectrum access policies, such as for example the spectrum licensing policies that are discussed in [Ofcom2600MHz].

Data PHY Error Model

The simulator includes an error model of the data plane (i.e., PDSCH and PUSCH) according to the standard link-to-system mapping (LSM) techniques. The choice is aligned with the standard system simulation methodology of OFDMA radio transmission technology. Thanks to LSM we are able to maintain a good level of accuracy and at the same time limiting the computational complexity increase. It is based on the mapping of single link layer performance obtained by means of link level simulators to system (in our case network) simulators. In particular link the layer simulator is used for generating the performance of a single link from a PHY layer perspective, usually in terms of code block error rate (BLER), under specific static conditions. LSM allows the usage of these parameters in more complex scenarios, typical of system/network simulators, where we have more links, interference and “colored” channel propagation phenomena (e.g., frequency selective fading).

To do this the Vienna LTE Simulator [ViennaLteSim] has been used for what concerns the extraction of link layer performance and the Mutual Information Based Effective SINR (MIESM) as LSM mapping function using part of the work recently published by the Signet Group of University of Padua [PaduaPEM].

MIESM

The specific LSM method adopted is the one based on the usage of a mutual information metric, commonly referred to as the mutual information per per coded bit (MIB or MMIB when a mean of multiples MIBs is involved). Another option would be represented by the Exponential ESM (EESM); however, recent studies demonstrate that MIESM outperforms EESM in terms of accuracy [LozanoCost].

_images/miesm_scheme.png

MIESM computational procedure diagram

The mutual information (MI) is dependent on the constellation mapping and can be calculated per transport block (TB) basis, by evaluating the MI over the symbols and the subcarrier. However, this would be too complex for a network simulator. Hence, in our implementation a flat channel response within the RB has been considered; therefore the overall MI of a TB is calculated averaging the MI evaluated per each RB used in the TB. In detail, the implemented scheme is depicted in Figure MIESM computational procedure diagram, where we see that the model starts by evaluating the MI value for each RB, represented in the figure by the SINR samples. Then the equivalent MI is evaluated per TB basis by averaging the MI values. Finally, a further step has to be done since the link level simulator returns the performance of the link in terms of block error rate (BLER) in a addive white gaussian noise (AWGN) channel, where the blocks are the code blocks (CBs) independently encoded/decoded by the turbo encoder. On this matter the standard 3GPP segmentation scheme has been used for estimating the actual CB size (described in section 5.1.2 of [TS36212]). This scheme divides the TB in N_{K_-} blocks of size K_- and N_{K+} blocks of size K_+. Therefore the overall TB BLER (TBLER) can be expressed as

TBLER = 1- \prod\limits_{i=1}^{C}(1-CBLER_i)

where the CBLER_i is the BLER of the CB i obtained according to the link level simulator CB BLER curves. For estimating the CBLER_i, the MI evaluation has been implemented according to its numerical approximation defined in [wimaxEmd]. Moreover, for reducing the complexity of the computation, the approximation has been converted into lookup tables. In detail, Gaussian cumulative model has been used for approximating the AWGN BLER curves with three parameters which provides a close fit to the standard AWGN performances, in formula:

CBLER_i = \frac{1}{2}\left[1-erf\left(\frac{x-b_{ECR}}{\sqrt{2}c_{ECR}} \right) \right]

where x is the MI of the TB, b_{ECR} represents the “transition center” and c_{ECR} is related to the “transition width” of the Gaussian cumulative distribution for each Effective Code Rate (ECR) which is the actual transmission rate according to the channel coding and MCS. For limiting the computational complexity of the model we considered only a subset of the possible ECRs in fact we would have potentially 5076 possible ECRs (i.e., 27 MCSs and 188 CB sizes). On this respect, we will limit the CB sizes to some representative values (i.e., 40, 140, 160, 256, 512, 1024, 2048, 4032, 6144), while for the others the worst one approximating the real one will be used (i.e., the smaller CB size value available respect to the real one). This choice is aligned to the typical performance of turbo codes, where the CB size is not strongly impacting on the BLER. However, it is to be notes that for CB sizes lower than 1000 bits the effect might be relevant (i.e., till 2 dB); therefore, we adopt this unbalanced sampling interval for having more precision where it is necessary. This behaviour is confirmed by the figures presented in the Annes Section.

BLER Curves

On this respect, we reused part of the curves obtained within [PaduaPEM]. In detail, we introduced the CB size dependency to the CB BLER curves with the support of the developers of [PaduaPEM] and of the LTE Vienna Simulator. In fact, the module released provides the link layer performance only for what concerns the MCSs (i.e, with a given fixed ECR). In detail the new error rate curves for each has been evaluated with a simulation campaign with the link layer simulator for a single link with AWGN noise and for CB size of 104, 140, 256, 512, 1024, 2048, 4032 and 6144. These curves has been mapped with the Gaussian cumulative model formula presented above for obtaining the correspondents b_{ECR} and c_{ECR} parameters.

The BLER performance of all MCS obtained with the link level simulator are plotted in the following figures (blue lines) together with their correspondent mapping to the Gaussian cumulative distribution (red dashed lines).

_images/MCS_1_4.png

BLER for MCS 1, 2, 3 and 4.

_images/MCS_5_8.png

BLER for MCS 5, 6, 7 and 8.

_images/MCS_9_12.png

BLER for MCS 9, 10, 11 and 12.

_images/MCS_13_16.png

BLER for MCS 13, 14, 15 and 16.

_images/MCS_17_20.png

BLER for MCS 17, 17, 19 and 20.

_images/MCS_21_24.png

BLER for MCS 21, 22, 23 and 24.

_images/MCS_25_28.png

BLER for MCS 25, 26, 27 and 28.

_images/MCS_29_29.png

BLER for MCS 29.

Integration of the BLER curves in the ns-3 LTE module

The model implemented uses the curves for the LSM of the recently LTE PHY Error Model released in the ns3 community by the Signet Group [PaduaPEM] and the new ones generated for different CB sizes. The LteSpectrumPhy class is in charge of evaluating the TB BLER thanks to the methods provided by the LteMiErrorModel class, which is in charge of evaluating the TB BLER according to the vector of the perceived SINR per RB, the MCS and the size in order to proper model the segmentation of the TB in CBs. In order to obtain the vector of the perceived SINRs for data and control signals, two instances of LteChunkProcessor (dedicated to evaluate the SINR for obtaining physical error performance) have been attached to UE downlink and eNB uplink LteSpectrumPhy modules for evaluating the error model distribution of PDSCH (UE side) and ULSCH (eNB side).

The model can be disabled for working with a zero-losses channel by setting the DataErrorModelEnabled attribute of the LteSpectrumPhy class (by default is active). This can be done according to the standard ns3 attribute system procedure, that is:

Config::SetDefault ("ns3::LteSpectrumPhy::DataErrorModelEnabled", BooleanValue (false));

Control Channels PHY Error Model

The simulator includes the error model for downlink control channels (PCFICH and PDCCH), while in uplink it is assumed and ideal error-free channel. The model is based on the MIESM approach presented before for considering the effects of the frequency selective channel since most of the control channels span the whole available bandwidth.

PCFICH + PDCCH Error Model

The model adopted for the error distribution of these channels is based on an evaluation study carried out in the RAN4 of 3GPP, where different vendors investigated the demodulation performance of the PCFICH jointly with PDCCH. This is due to the fact that the PCFICH is the channel in charge of communicating to the UEs the actual dimension of the PDCCH (which spans between 1 and 3 symbols); therefore the correct decodification of the DCIs depends on the correct interpretation of both ones. In 3GPP this problem have been evaluated for improving the cell-edge performance [FujitsuWhitePaper], where the interference among neighboring cells can be relatively high due to signal degradation. A similar problem has been notices in femto-cell scenario and, more in general, in HetNet scenarios the bottleneck has been detected mainly as the PCFICH channel [Bharucha2011], where in case of many eNBs are deployed in the same service area, this channel may collide in frequency, making impossible the correct detection of the PDCCH channel, too.

In the simulator, the SINR perceived during the reception has been estimated according to the MIESM model presented above in order to evaluate the error distribution of PCFICH and PDCCH. In detail, the SINR samples of all the RBs are included in the evaluation of the MI associated to the control frame and, according to this values, the effective SINR (eSINR) is obtained by inverting the MI evaluation process. It has to be noted that, in case of MIMO transmission, both PCFICH and the PDCCH use always the transmit diversity mode as defined by the standard. According to the eSINR perceived the decodification error probability can be estimated as function of the results presented in [R4-081920]. In case an error occur, the DCIs discarded and therefore the UE will be not able to receive the correspondent Tbs, therefore resulting lost.

MIMO Model

The use of multiple antennas both at transmitter and receiver side, known as multiple-input and multiple-output (MIMO), is a problem well studied in literature during the past years. Most of the work concentrate on evaluating analytically the gain that the different MIMO schemes might have in term of capacity; however someones provide also information of the gain in terms of received power [CatreuxMIMO].

According to the considerations above, a model more flexible can be obtained considering the gain that MIMO schemes bring in the system from a statistical point of view. As highlighted before, [CatreuxMIMO] presents the statistical gain of several MIMO solutions respect to the SISO one in case of no correlation between the antennas. In the work the gain is presented as the cumulative distribution function (CDF) of the output SINR for what concern SISO, MIMO-Alamouti, MIMO-MMSE, MIMO-OSIC-MMSE and MIMO-ZF schemes. Elaborating the results, the output SINR distribution can be approximated with a log-normal one with different mean and variance as function of the scheme considered. However, the variances are not so different and they are approximatively equal to the one of the SISO mode already included in the shadowing component of the BuildingsPropagationLossModel, in detail:

  • SISO: \mu = 13.5 and \sigma = 20 [dB].

  • MIMO-Alamouti: \mu = 17.7 and \sigma = 11.1 [dB].

  • MIMO-MMSE: \mu = 10.7 and \sigma = 16.6 [dB].

  • MIMO-OSIC-MMSE: \mu = 12.6 and \sigma = 15.5 [dB].

  • MIMO-ZF: \mu = 10.3 and \sigma = 12.6 [dB].

Therefore the PHY layer implements the MIMO model as the gain perceived by the receiver when using a MIMO scheme respect to the one obtained using SISO one. We note that, these gains referred to a case where there is no correlation between the antennas in MIMO scheme; therefore do not model degradation due to paths correlation.

UE PHY Measurements Model

According to [TS36214], the UE has to report a set of measurements of the eNBs that the device is able to perceive: the reference signal received power (RSRP) and the reference signal received quality (RSRQ). The former is a measure of the received power of a specific eNB, while the latter includes also channel interference and thermal noise. The UE has to report the measurements jointly with the physical cell identity (PCI) of the cell. Both the RSRP and RSRQ measurements are performed during the reception of the RS, while the PCI is obtained with the Primary Synchronization Signal (PSS). The PSS is sent by the eNB each 5 subframes and in detail in the subframes 1 and 6. In real systems, only 504 distinct PCIs are available, and hence it could occur that two nearby eNBs use the same PCI; however, in the simulator we model PCIs using simulation metadata, and we allow up to 65535 distinct PCIs, thereby avoiding PCI collisions provided that less that 65535 eNBs are simulated in the same scenario.

According to [TS36133] sections 9.1.4 and 9.1.7, RSRP is reported by PHY layer in dBm while RSRQ in dB. The values of RSRP and RSRQ are provided to higher layers through the C-PHY SAP (by means of UeMeasurementsParameters struct) every 200 ms as defined in [TS36331]. Layer 1 filtering is performed by averaging the all the measurements collected during the last window slot. The periodicity of reporting can be adjusted for research purposes by means of the LteUePhy::UeMeasurementsFilterPeriod attribute.

The formulas of the RSRP and RSRQ can be simplified considering the assumption of the PHY layer that the channel is flat within the RB, the finest level of accuracy. In fact, this implies that all the REs within a RB have the same power, therefore:

RSRP = \frac{\sum_{k=0}^{K-1}\frac{\sum_{m=0}^{M-1}(P(k,m))}{M}}{K}
     = \frac{\sum_{k=0}^{K-1}\frac{(M \times P(k))}{M}}{K}
     = \frac{\sum_{k=0}^{K-1}(P(k))}{K}

where P(k,m) represents the signal power of the RE m within the RB k, which, as observed before, is constant within the same RB and equal to P(k), M is the number of REs carrying the RS in a RB and K is the number of RBs. It is to be noted that P(k), and in general all the powers defined in this section, is obtained in the simulator from the PSD of the RB (which is provided by the LteInterferencePowerChunkProcessor), in detail:

P(k) = PSD_{RB}(k)*180000/12

where PSD_{RB}(k) is the power spectral density of the RB k, 180000 is the bandwidth in Hz of the RB and 12 is the number of REs per RB in an OFDM symbol. Similarly, for RSSI we have

RSSI = \sum_{k=0}^{K-1} \frac{\sum_{s=0}^{S-1} \sum_{r=0}^{R-1}( P(k,s,r) + I(k,s,r) + N(k,s,r))}{S}

where S is the number of OFDM symbols carrying RS in a RB and R is the number of REs carrying a RS in a OFDM symbol (which is fixed to 2) while P(k,s,r), I(k,s,r) and N(k,s,r) represent respectively the perceived power of the serving cell, the interference power and the noise power of the RE r in symbol s. As for RSRP, the measurements within a RB are always equals among each others according to the PHY model; therefore P(k,s,r) = P(k), I(k,s,r) = I(k) and N(k,s,r) = N(k), which implies that the RSSI can be calculated as:

RSSI = \sum_{k=0}^{K-1} \frac{S \times 2 \times ( P(k) + I(k) + N(k))}{S}
     = \sum_{k=0}^{K-1} 2 \times ( P(k) + I(k) + N (k))

Considering the constraints of the PHY reception chain implementation, and in order to maintain the level of computational complexity low, only RSRP can be directly obtained for all the cells. This is due to the fact that LteSpectrumPhy is designed for evaluating the interference only respect to the signal of the serving eNB. This implies that the PHY layer is optimized for managing the power signals information with the serving eNB as a reference. However, RSRP and RSRQ of neighbor cell i can be extracted by the current information available of the serving cell j as detailed in the following:

RSRP_i = \frac{\sum_{k=0}^{K-1}(P_i(k))}{K}

RSSI_i = RSSI_j = \sum_{k=0}^{K-1} 2 \times ( I_j(k) + P_j(k) + N_j(k) )

RSRQ_i^j = K \times RSRP_i / RSSI_j

where RSRP_i is the RSRP of the neighbor cell i, P_i(k) is the power perceived at any RE within the RB k, K is the total number of RBs, RSSI_i is the RSSI of the neighbor cell i when the UE is attached to cell j (which, since it is the sum of all the received powers, coincides with RSSI_j), I_j(k) is the total interference perceived by UE in any RE of RB k when attached to cell i (obtained by the LteInterferencePowerChunkProcessor), P_j(k) is the power perceived of cell j in any RE of the RB k and N is the power noise spectral density in any RE. The sample is considered as valid in case of the RSRQ evaluated is above the LteUePhy::RsrqUeMeasThreshold attribute.

HARQ

The HARQ scheme implemented is based on a incremental redundancy (IR) solutions combined with multiple stop-and-wait processes for enabling a continuous data flow. In detail, the solution adopted is the soft combining hybrid IR Full incremental redundancy (also called IR Type II), which implies that the retransmissions contain only new information respect to the previous ones. The resource allocation algorithm of the HARQ has been implemented within the respective scheduler classes (i.e., RrFfMacScheduler and PfFfMacScheduler, refer to their correspondent sections for more info), while the decodification part of the HARQ has been implemented in the LteSpectrumPhy and LteHarqPhy classes which will be detailed in this section.

According to the standard, the UL retransmissions are synchronous and therefore are allocated 7 ms after the original transmission. On the other hand, for the DL, they are asynchronous and therefore can be allocated in a more flexible way starting from 7 ms and it is a matter of the specific scheduler implementation. The HARQ processes behavior is depicted in Figure:ref:fig-harq-processes-scheme.

At the MAC layer, the HARQ entity residing in the scheduler is in charge of controlling the 8 HARQ processes for generating new packets and managing the retransmissions both for the DL and the UL. The scheduler collects the HARQ feedback from eNB and UE PHY layers (respectively for UL and DL connection) by means of the FF API primitives SchedUlTriggerReq and SchedUlTriggerReq. According to the HARQ feedback and the RLC buffers status, the scheduler generates a set of DCIs including both retransmissions of HARQ blocks received erroneous and new transmissions, in general, giving priority to the former. On this matter, the scheduler has to take into consideration one constraint when allocating the resource for HARQ retransmissions, it must use the same modulation order of the first transmission attempt (i.e., QPSK for MCS \in [0..9], 16QAM for MCS \in [10..16] and 64QAM for MCS \in [17..28]). This restriction comes from the specification of the rate matcher in the 3GPP standard [ TS36212]_, where the algorithm fixes the modulation order for generating the different blocks of the redundancy versions.

The PHY Error Model model (i.e., the LteMiErrorModel class already presented before) has been extended for considering IR HARQ according to [wimaxEmd], where the parameters for the AWGN curves mapping for MIESM mapping in case of retransmissions are given by:

R_{eff} = \frac{X}{\sum\limits_{i=1}^q C_i}

M_{I eff} = \frac{\sum\limits_{i=1}^q C_i M_i}{\sum\limits_{i=1}^q C_i}

where X is the number of original information bits, C_i are number of coded bits, M_i are the mutual information per HARQ block received on the total number of q retransmissions. Therefore, in order to be able to return the error probability with the error model implemented in the simulator evaluates the R_{eff} and the MI_{I eff} and return the value of error probability of the ECR of the same modulation with closest lower rate respect to the R_{eff}. In order to consider the effect of HARQ retransmissions a new sets of curves have been integrated respect to the standard one used for the original MCS. The new curves are intended for covering the cases when the most conservative MCS of a modulation is used which implies the generation of R_{eff} lower respect to the one of standard MCSs. On this matter the curves for 1, 2 and 3 retransmissions have been evaluated for 10 and 17. For MCS 0 we considered only the first retransmission since the produced code rate is already very conservative (i.e., 0.04) and returns an error rate enough robust for the reception (i.e., the downturn of the BLER is centered around -18 dB). It is to be noted that, the size of first TB transmission has been assumed as containing all the information bits to be coded; therefore X is equal to the size of the first TB sent of a an HARQ process. The model assumes that the eventual presence of parity bits in the codewords is already considered in the link level curves. This implies that as soon as the minimum R_{eff} is reached the model is not including the gain due to the transmission of further parity bits.

_images/lte-harq-processes-scheme.png

HARQ processes behavior in LTE

The part of HARQ devoted to manage the decodification of the HARQ blocks has been implemented in the LteHarqPhy and LteSpectrumPhy classes. The former is in charge of maintaining the HARQ information for each active process . The latter interacts with LteMiErrorModel class for evaluating the correctness of the blocks received and includes the messaging algorithm in charge of communicating to the HARQ entity in the scheduler the result of the decodifications. These messages are encapsulated in the dlInfoListElement for DL and ulInfoListElement for UL and sent through the PUCCH and the PHICH respectively with an ideal error free model according to the assumptions in their implementation. A sketch of the iteration between HARQ and LTE protocol stack in represented in Figure:ref:fig-harq-architecture.

Finally, the HARQ engine is always active both at MAC and PHY layer; however, in case of the scheduler does not support HARQ the system will continue to work with the HARQ functions inhibited (i.e., buffers are filled but not used). This implementation characteristic gives backward compatibility with schedulers implemented before HARQ integration.

_images/lte-harq-architecture.png

Interaction between HARQ and LTE protocol stack

MAC

Resource Allocation Model

We now briefly describe how resource allocation is handled in LTE, clarifying how it is modeled in the simulator. The scheduler is in charge of generating specific structures called Data Control Indication (DCI) which are then transmitted by the PHY of the eNB to the connected UEs, in order to inform them of the resource allocation on a per subframe basis. In doing this in the downlink direction, the scheduler has to fill some specific fields of the DCI structure with all the information, such as: the Modulation and Coding Scheme (MCS) to be used, the MAC Transport Block (TB) size, and the allocation bitmap which identifies which RBs will contain the data transmitted by the eNB to each user.

For the mapping of resources to physical RBs, we adopt a localized mapping approach (see [Sesia2009], Section 9.2.2.1); hence in a given subframe each RB is always allocated to the same user in both slots. The allocation bitmap can be coded in different formats; in this implementation, we considered the Allocation Type 0 defined in [TS36213], according to which the RBs are grouped in Resource Block Groups (RBG) of different size determined as a function of the Transmission Bandwidth Configuration in use.

For certain bandwidth values not all the RBs are usable, since the group size is not a common divisor of the group. This is for instance the case when the bandwidth is equal to 25 RBs, which results in a RBG size of 2 RBs, and therefore 1 RB will result not addressable. In uplink the format of the DCIs is different, since only adjacent RBs can be used because of the SC-FDMA modulation. As a consequence, all RBs can be allocated by the eNB regardless of the bandwidth configuration.

Adaptive Modulation and Coding

The simulator provides two Adaptive Modulation and Coding (AMC) models: one based on the GSoC model [Piro2011] and one based on the physical error model (described in the following sections).

The former model is a modified version of the model described in [Piro2011], which in turn is inspired from [Seo2004]. Our version is described in the following. Let i denote the generic user, and let \gamma_i be its SINR. We get the spectral efficiency \eta_i of user i using the following equations:

\mathrm{BER} = 0.00005

\Gamma = \frac{ -\ln{ (5 * \mathrm{BER}) } }{ 1.5}

\eta_i = \log_2 { \left( 1 + \frac{ {\gamma}_i }{ \Gamma } \right)}

The procedure described in [R1-081483] is used to get the corresponding MCS scheme. The spectral efficiency is quantized based on the channel quality indicator (CQI), rounding to the lowest value, and is mapped to the corresponding MCS scheme.

Finally, we note that there are some discrepancies between the MCS index in [R1-081483] and that indicated by the standard: [TS36213] Table 7.1.7.1-1 says that the MCS index goes from 0 to 31, and 0 appears to be a valid MCS scheme (TB size is not 0) but in [R1-081483] the first useful MCS index is 1. Hence to get the value as intended by the standard we need to subtract 1 from the index reported in [R1-081483].

The alternative model is based on the physical error model developed for this simulator and explained in the following subsections. This scheme is able to adapt the MCS selection to the actual PHY layer performance according to the specific CQI report. According to their definition, a CQI index is assigned when a single PDSCH TB with the modulation coding scheme and code rate correspondent to that CQI index in table 7.2.3-1 of [TS36213] can be received with an error probability less than 0.1. In case of wideband CQIs, the reference TB includes all the RBGs available in order to have a reference based on the whole available resources; while, for subband CQIs, the reference TB is sized as the RBGs.

Transport Block model

The model of the MAC Transport Blocks (TBs) provided by the simulator is simplified with respect to the 3GPP specifications. In particular, a simulator-specific class (PacketBurst) is used to aggregate MAC SDUs in order to achieve the simulator’s equivalent of a TB, without the corresponding implementation complexity. The multiplexing of different logical channels to and from the RLC layer is performed using a dedicated packet tag (LteRadioBearerTag), which performs a functionality which is partially equivalent to that of the MAC headers specified by 3GPP.

The FemtoForum MAC Scheduler Interface

This section describes the ns-3 specific version of the LTE MAC Scheduler Interface Specification published by the FemtoForum [FFAPI].

We implemented the ns-3 specific version of the FemtoForum MAC Scheduler Interface [FFAPI] as a set of C++ abstract classes; in particular, each primitive is translated to a C++ method of a given class. The term implemented here is used with the same meaning adopted in [FFAPI], and hence refers to the process of translating the logical interface specification to a particular programming language. The primitives in [FFAPI] are grouped in two groups: the CSCHED primitives, which deal with scheduler configuration, and the SCHED primitives, which deal with the execution of the scheduler. Furthermore, [FFAPI] defines primitives of two different kinds: those of type REQ go from the MAC to the Scheduler, and those of type IND/CNF go from the scheduler to the MAC. To translate these characteristics into C++, we define the following abstract classes that implement Service Access Points (SAPs) to be used to issue the primitives:

  • the FfMacSchedSapProvider class defines all the C++ methods that correspond to SCHED primitives of type REQ;

  • the FfMacSchedSapUser class defines all the C++ methods that correspond to SCHED primitives of type CNF/IND;

  • the FfMacCschedSapProvider class defines all the C++ methods that correspond to CSCHED primitives of type REQ;

  • the FfMacCschedSapUser class defines all the C++ methods that correspond to CSCHED primitives of type CNF/IND;

There are 3 blocks involved in the MAC Scheduler interface: Control block, Subframe block and Scheduler block. Each of these blocks provide one part of the MAC Scheduler interface. The figure below shows the relationship between the blocks and the SAPs defined in our implementation of the MAC Scheduler Interface.

_images/ff-mac-saps.png

In addition to the above principles, the following design choices have been taken:

  • The definition of the MAC Scheduler interface classes follows the naming conventions of the ns-3 Coding Style. In particular, we follow the CamelCase convention for the primitive names. For example, the primitive CSCHED_CELL_CONFIG_REQ is translated to CschedCellConfigReq in the ns-3 code.

  • The same naming conventions are followed for the primitive parameters. As the primitive parameters are member variables of classes, they are also prefixed with a m_.

  • regarding the use of vectors and lists in data structures, we note that [FFAPI] is a pretty much C-oriented API. However, considered that C++ is used in ns-3, and that the use of C arrays is discouraged, we used STL vectors (std::vector) for the implementation of the MAC Scheduler Interface, instead of using C arrays as implicitly suggested by the way [FFAPI] is written.

  • In C++, members with constructors and destructors are not allow in unions. Hence all those data structures that are said to be unions in [FFAPI] have been defined as structs in our code.

The figure below shows how the MAC Scheduler Interface is used within the eNB.

_images/ff-example.png

The User side of both the CSCHED SAP and the SCHED SAP are implemented within the eNB MAC, i.e., in the file lte-enb-mac.cc. The eNB MAC can be used with different scheduler implementations without modifications. The same figure also shows, as an example, how the Round Robin Scheduler is implemented: to interact with the MAC of the eNB, the Round Robin scheduler implements the Provider side of the SCHED SAP and CSCHED SAP interfaces. A similar approach can be used to implement other schedulers as well. A description of each of the scheduler implementations that we provide as part of our LTE simulation module is provided in the following subsections.

Round Robin (RR) Scheduler

The Round Robin (RR) scheduler is probably the simplest scheduler found in the literature. It works by dividing the available resources among the active flows, i.e., those logical channels which have a non-empty RLC queue. If the number of RBGs is greater than the number of active flows, all the flows can be allocated in the same subframe. Otherwise, if the number of active flows is greater than the number of RBGs, not all the flows can be scheduled in a given subframe; then, in the next subframe the allocation will start from the last flow that was not allocated. The MCS to be adopted for each user is done according to the received wideband CQIs.

For what concern the HARQ, RR implements the non adaptive version, which implies that in allocating the retransmission attempts RR uses the same allocation configuration of the original block, which means maintaining the same RBGs and MCS. UEs that are allocated for HARQ retransmissions are not considered for the transmission of new data in case they have a transmission opportunity available in the same TTI. Finally, HARQ can be disabled with ns3 attribute system for maintaining backward compatibility with old test cases and code, in detail:

Config::SetDefault ("ns3::RrFfMacScheduler::HarqEnabled", BooleanValue (false));

The scheduler implements the filtering of the uplink CQIs according to their nature with UlCqiFilter attribute, in detail:

  • SRS_UL_CQI: only SRS based CQI are stored in the internal attributes.

  • PUSCH_UL_CQI: only PUSCH based CQI are stored in the internal attributes.

Proportional Fair (PF) Scheduler

The Proportional Fair (PF) scheduler [Sesia2009] works by scheduling a user when its instantaneous channel quality is high relative to its own average channel condition over time. Let i,j denote generic users; let t be the subframe index, and k be the resource block index; let M_{i,k}(t) be MCS usable by user i on resource block k according to what reported by the AMC model (see Adaptive Modulation and Coding); finally, let S(M, B) be the TB size in bits as defined in [TS36213] for the case where a number B of resource blocks is used. The achievable rate R_{i}(k,t) in bit/s for user i on resource block group k at subframe t is defined as

R_{i}(k,t) =  \frac{S\left( M_{i,k}(t), 1\right)}{\tau}

where \tau is the TTI duration. At the start of each subframe t, each RBG is assigned to a certain user. In detail, the index \widehat{i}_{k}(t) to which RBG k is assigned at time t is determined as

\widehat{i}_{k}(t) = \underset{j=1,...,N}{\operatorname{argmax}}
 \left( \frac{ R_{j}(k,t) }{ T_\mathrm{j}(t) } \right)

where T_{j}(t) is the past througput performance perceived by the user j. According to the above scheduling algorithm, a user can be allocated to different RBGs, which can be either adjacent or not, depending on the current condition of the channel and the past throughput performance T_{j}(t). The latter is determined at the end of the subframe t using the following exponential moving average approach:

T_{j}(t) =
(1-\frac{1}{\alpha})T_{j}(t-1)
+\frac{1}{\alpha} \widehat{T}_{j}(t)

where \alpha is the time constant (in number of subframes) of the exponential moving average, and \widehat{T}_{j}(t) is the actual throughput achieved by the user i in the subframe t. \widehat{T}_{j}(t) is measured according to the following procedure. First we determine the MCS \widehat{M}_j(t) actually used by user j:

\widehat{M}_j(t) = \min_{k: \widehat{i}_{k}(t) = j}{M_{j,k}(t)}

then we determine the total number \widehat{B}_j(t) of RBGs allocated to user j:

\widehat{B}_j(t) = \left| \{ k :  \widehat{i}_{k}(t) = j \} \right|

where |\cdot| indicates the cardinality of the set; finally,

\widehat{T}_{j}(t) = \frac{S\left( \widehat{M}_j(t), \widehat{B}_j(t)
\right)}{\tau}

For what concern the HARQ, PF implements the non adaptive version, which implies that in allocating the retransmission attempts the scheduler uses the same allocation configuration of the original block, which means maintaining the same RBGs and MCS. UEs that are allocated for HARQ retransmissions are not considered for the transmission of new data in case they have a transmission opportunity available in the same TTI. Finally, HARQ can be disabled with ns3 attribute system for maintaining backward compatibility with old test cases and code, in detail:

Config::SetDefault ("ns3::PfFfMacScheduler::HarqEnabled", BooleanValue (false));

Maximum Throughput (MT) Scheduler

The Maximum Throughput (MT) scheduler [FCapo2012] aims to maximize the overall throughput of eNB. It allocates each RB to the user that can achieve the maximum achievable rate in the current TTI. Currently, MT scheduler in NS-3 has two versions: frequency domain (FDMT) and time domain (TDMT). In FDMT, every TTI, MAC scheduler allocates RBGs to the UE who has highest achievable rate calculated by subband CQI. In TDMT, every TTI, MAC scheduler selects one UE which has highest achievable rate calculated by wideband CQI. Then MAC scheduler allocates all RBGs to this UE in current TTI. The calculation of achievable rate in FDMT and TDMT is as same as the one in PF. Let i,j denote generic users; let t be the subframe index, and k be the resource block index; let M_{i,k}(t) be MCS usable by user i on resource block k according to what reported by the AMC model (see Adaptive Modulation and Coding); finally, let S(M, B) be the TB size in bits as defined in [TS36213] for the case where a number B of resource blocks is used. The achievable rate R_{i}(k,t) in bit/s for user i on resource block k at subframe t is defined as

R_{i}(k,t) =  \frac{S\left( M_{i,k}(t), 1\right)}{\tau}

where \tau is the TTI duration. At the start of each subframe t, each RB is assigned to a certain user. In detail, the index \widehat{i}_{k}(t) to which RB k is assigned at time t is determined as

\widehat{i}_{k}(t) = \underset{j=1,...,N}{\operatorname{argmax}}
    \left( { R_{j}(k,t) } \right)

When there are several UEs having the same achievable rate, current implementation always selects the first UE created in script. Although MT can maximize cell throughput, it cannot provide fairness to UEs in poor channel condition.

Throughput to Average (TTA) Scheduler

The Throughput to Average (TTA) scheduler [FCapo2012] can be considered as an intermediate between MT and PF. The metric used in TTA is calculated as follows:

\widehat{i}_{k}(t) = \underset{j=1,...,N}{\operatorname{argmax}}
 \left( \frac{ R_{j}(k,t) }{ R_{j}(t) } \right)

Here, R_{i}(k,t) in bit/s represents the achievable rate for user i on resource block k at subframe t. The calculation method already is shown in MT and PF. Meanwhile, R_{i}(t) in bit/s stands for the achievable rate for i at subframe t. The difference between those two achievable rates is how to get MCS. For R_{i}(k,t), MCS is calculated by subband CQI while R_{i}(t) is calculated by wideband CQI. TTA scheduler can only be implemented in frequency domain (FD) because the achievable rate of particular RBG is only related to FD scheduling.

Blind Average Throughput Scheduler

The Blind Average Throughput scheduler [FCapo2012] aims to provide equal throughput to all UEs under eNB. The metric used in TTA is calculated as follows:

\widehat{i}_{k}(t) = \underset{j=1,...,N}{\operatorname{argmax}}
 \left( \frac{ 1 }{ T_\mathrm{j}(t) } \right)

where T_{j}(t) is the past throughput performance perceived by the user j and can be calculated by the same method in PF scheduler. In the time domain blind average throughput (TD-BET), the scheduler selects the UE with largest priority metric and allocates all RBGs to this UE. On the other hand, in the frequency domain blind average throughput (FD-BET), every TTI, the scheduler first selects one UE with lowest pastAverageThroughput (largest priority metric). Then scheduler assigns one RBG to this UE, it calculates expected throughput of this UE and uses it to compare with past average throughput T_{j}(t) of other UEs. The scheduler continues to allocate RBG to this UE until its expected throughput is not the smallest one among past average throughput T_{j}(t) of all UE. Then the scheduler will use the same way to allocate RBG for a new UE which has the lowest past average throughput T_{j}(t) until all RBGs are allocated to UEs. The principle behind this is that, in every TTI, the scheduler tries the best to achieve the equal throughput among all UEs.

Token Bank Fair Queue Scheduler

Token Bank Fair Queue (TBFQ) is a QoS aware scheduler which derives from the leaky-bucket mechanism. In TBFQ, a traffic flow of user i is characterized by following parameters:

  • t_{i}: packet arrival rate (byte/sec )

  • r_{i}: token generation rate (byte/sec)

  • p_{i}: token pool size (byte)

  • E_{i}: counter that records the number of token borrowed from or given to the token bank by flow i ; E_{i} can be smaller than zero

Each K bytes data consumes k tokens. Also, TBFQ maintains a shared token bank (B) so as to balance the traffic between different flows. If token generation rate r_{i} is bigger than packet arrival rate t_{i}, then tokens overflowing from token pool are added to the token bank, and E_{i} is increased by the same amount. Otherwise, flow i needs to withdraw tokens from token bank based on a priority metric frac{E_{i}}{r_{i}}, and E_{i} is decreased. Obviously, the user contributes more on token bank has higher priority to borrow tokens; on the other hand, the user borrows more tokens from bank has lower priority to continue to withdraw tokens. Therefore, in case of several users having the same token generation rate, traffic rate and token pool size, user suffers from higher interference has more opportunity to borrow tokens from bank. In addition, TBFQ can police the traffic by setting the token generation rate to limit the throughput. Additionally, TBFQ also maintains following three parameters for each flow:

  • Debt limit d_{i}: if E_{i} belows this threshold, user i cannot further borrow tokens from bank. This is for preventing malicious UE to borrow too much tokens.

  • Credit limit c_{i}: the maximum number of tokens UE i can borrow from the bank in one time.

  • Credit threshold C: once E_{i} reaches debt limit, UE i must store C tokens to bank in order to further borrow token from bank.

LTE in NS-3 has two versions of TBFQ scheduler: frequency domain TBFQ (FD-TBFQ) and time domain TBFQ (TD-TBFQ). In FD-TBFQ, the scheduler always select UE with highest metric and allocates RBG with highest subband CQI until there are no packets within UE’s RLC buffer or all RBGs are allocated [FABokhari2009]. In TD-TBFQ, after selecting UE with maximum metric, it allocates all RBGs to this UE by using wideband CQI [WKWong2004].

Priority Set Scheduler

Priority set scheduler (PSS) is a QoS aware scheduler which combines time domain (TD) and frequency domain (FD) packet scheduling operations into one scheduler [GMonghal2008]. It controls the fairness among UEs by a specified Target Bit Rate (TBR).

In TD scheduler part, PSS first selects UEs with non-empty RLC buffer and then divide them into two sets based on the TBR:

  • set 1: UE whose past average throughput is smaller than TBR; TD scheduler calculates their priority metric in Blind Equal Throughput (BET) style:

\widehat{i}_{k}(t) = \underset{j=1,...,N}{\operatorname{argmax}}
 \left( \frac{ 1 }{ T_\mathrm{j}(t) } \right)

  • set 2: UE whose past average throughput is larger (or equal) than TBR; TD scheduler calculates their priority metric in Proportional Fair (PF) style:

\widehat{i}_{k}(t) = \underset{j=1,...,N}{\operatorname{argmax}}
 \left( \frac{ R_{j}(k,t) }{ T_\mathrm{j}(t) } \right)

UEs belonged to set 1 have higher priority than ones in set 2. Then PSS will select N_{mux} UEs with highest metric in two sets and forward those UE to FD scheduler. In PSS, FD scheduler allocates RBG k to UE n that maximums the chosen metric. Two PF schedulers are used in PF scheduler:

  • Proportional Fair scheduled (PFsch)

\widehat{Msch}_{k}(t) = \underset{j=1,...,N}{\operatorname{argmax}}
 \left( \frac{ R_{j}(k,t) }{ Tsch_\mathrm{j}(t) } \right)

  • Carrier over Interference to Average (CoIta)

\widehat{Mcoi}_{k}(t) = \underset{j=1,...,N}{\operatorname{argmax}}
 \left( \frac{ CoI[j,k] }{ \sum_{k=0}^{N_{RBG}} CoI[j,k] } \right)

where Tsch_{j}(t) is similar past throughput performance perceived by the user j, with the difference that it is updated only when the i-th user is actually served. CoI[j,k] is an estimation of the SINR on the RBG k of UE j. Both PFsch and CoIta is for decoupling FD metric from TD scheduler. In addition, PSS FD scheduler also provide a weight metric W[n] for helping controlling fairness in case of low number of UEs.

W[n] =  max (1, \frac{TBR}{ T_{j}(t) })

where T_{j}(t) is the past throughput performance perceived by the user j . Therefore, on RBG k, the FD scheduler selects the UE j that maximizes the product of the frequency domain metric (Msch, MCoI) by weight W[n]. This strategy will guarantee the throughput of lower quality UE tend towards the TBR.

Config::SetDefault ("ns3::PfFfMacScheduler::HarqEnabled", BooleanValue (false));

The scheduler implements the filtering of the uplink CQIs according to their nature with UlCqiFilter attribute, in detail:

  • SRS_UL_CQI: only SRS based CQI are stored in the internal attributes.

  • PUSCH_UL_CQI: only PUSCH based CQI are stored in the internal attributes.

Channel and QoS Aware Scheduler

The Channel and QoS Aware (CQA) Scheduler [Bbojovic2014] is an LTE MAC downlink scheduling algorithm that considers the head of line (HOL) delay, the GBR parameters and channel quality over different subbands. The CQA scheduler is based on joint TD and FD scheduling.

In the TD (at each TTI) the CQA scheduler groups users by priority. The purpose of grouping is to enforce the FD scheduling to consider first the flows with highest HOL delay. The grouping metric m_{td} for user j=1,...,N is defined in the following way:

m_{td}^{j}(t) = \lceil\frac{d_{hol}^{j}(t)}{g}\rceil \;,

where d_{hol}^{j}(t) is the current value of HOL delay of flow j, and g is a grouping parameter that determines granularity of the groups, i.e. the number of the flows that will be considered in the FD scheduling iteration.

The groups of flows selected in the TD iteration are forwarded to the FD scheduling starting from the flows with the highest value of the m_{td} metric until all RBGs are assigned in the corresponding TTI. In the FD, for each RBG k=1,...,K, the CQA scheduler assigns the current RBG to the user j that has the maximum value of the FD metric which we define in the following way:

m_{fd}^{(k,j)}(t) = d_{HOL}^{j}(t) \cdot m_{GBR}^j(t) \cdot m_{ca}^{k,j}(t) \;,

where m_{GBR}^j(t) is calculated as follows:

m_{GBR}^j(t)=\frac{GBR^j}{\overline{R^j}(t)}=\frac{GBR^j}{(1-\alpha)\cdot\overline{R^j}(t-1)+\alpha \cdot r^j(t)} \;,

where GBR^j is the bit rate specified in EPS bearer of the flow j, \overline{R^j}(t) is the past averaged throughput that is calculated with a moving average, r^{j}(t) is the throughput achieved at the time t, and \alpha is a coefficient such that 0 \le \alpha
\le1.

For m_{ca}^{(k,j)}(t) we consider two different metrics: m_{pf}^{(k,j)}(t) and m_{ff}^{(k,j)}(t). m_{pf} is the Proportional Fair metric which is defined as follows:

m_{pf}^{(k,j)}(t) = \frac{R_e^{(k,j)}}{\overline{R^j}(t)} \;,

where R_e^{(k,j)}(t) is the estimated achievable throughput of user j over RBG k calculated by the Adaptive Modulation and Coding (AMC) scheme that maps the channel quality indicator (CQI) value to the transport block size in bits.

The other channel awareness metric that we consider is m_{ff} which is proposed in [GMonghal2008] and it represents the frequency selective fading gains over RBG k for user j and is calculated in the following way:

m_{ff}^{(k,j)}(t) = \frac{CQI^{(k,j)}(t)}{\sum_{k=1}^{K}CQI(t)^{(k,j)}} \;,

where CQI^{(k,j)}(t) is the last reported CQI value from user j for the k-th RBG.

The user can select whether m_{pf} or m_{ff} is used by setting the attribute ns3::CqaFfMacScheduler::CqaMetric respectively to "CqaPf" or "CqaFf".

Random Access

The LTE model includes a model of the Random Access procedure based on some simplifying assumptions, which are detailed in the following for each of the messages and signals described in the specs [TS36321].

  • Random Access (RA) preamble: in real LTE systems this corresponds to a Zadoff-Chu (ZC) sequence using one of several formats available and sent in the PRACH slots which could in principle overlap with PUSCH. PRACH Configuration Index 14 is assumed, i.e., preambles can be sent on any system frame number and subframe number. The RA preamble is modeled using the LteControlMessage class, i.e., as an ideal message that does not consume any radio resources. The collision of preamble transmission by multiple UEs in the same cell are modeled using a protocol interference model, i.e., whenever two or more identical preambles are transmitted in same cell at the same TTI, no one of these identical preambles will be received by the eNB. Other than this collision model, no error model is associated with the reception of a RA preamble.

  • Random Access Response (RAR): in real LTE systems, this is a special MAC PDU sent on the DL-SCH. Since MAC control elements are not accurately modeled in the simulator (only RLC and above PDUs are), the RAR is modeled as an LteControlMessage that does not consume any radio resources. Still, during the RA procedure, the LteEnbMac will request to the scheduler the allocation of resources for the RAR using the FF MAC Scheduler primitive SCHED_DL_RACH_INFO_REQ. Hence, an enhanced scheduler implementation (not available at the moment) could allocate radio resources for the RAR, thus modeling the consumption of Radio Resources for the transmission of the RAR.

  • Message 3: in real LTE systems, this is an RLC TM SDU sent over resources specified in the UL Grant in the RAR. In the simulator, this is modeled as a real RLC TM RLC PDU whose UL resources are allocated by the scheduler upon call to SCHED_DL_RACH_INFO_REQ.

  • Contention Resolution (CR): in real LTE system, the CR phase is needed to address the case where two or more UE sent the same RA preamble in the same TTI, and the eNB was able to detect this preamble in spite of the collision. Since this event does not occur due to the protocol interference model used for the reception of RA preambles, the CR phase is not modeled in the simulator, i.e., the CR MAC CE is never sent by the eNB and the UEs consider the RA to be successful upon reception of the RAR. As a consequence, the radio resources consumed for the transmission of the CR MAC CE are not modeled.

Figure Sequence diagram of the Contention-based MAC Random Access procedure and Sequence diagram of the Non-contention-based MAC Random Access procedure shows the sequence diagrams of respectively the contention-based and non-contention-based MAC random access procedure, highlighting the interactions between the MAC and the other entities.

_images/mac-random-access-contention.png

Sequence diagram of the Contention-based MAC Random Access procedure

_images/mac-random-access-noncontention.png

Sequence diagram of the Non-contention-based MAC Random Access procedure

RLC

Overview

The RLC entity is specified in the 3GPP technical specification [TS36322], and comprises three different types of RLC: Transparent Mode (TM), Unacknowledged Mode (UM) and Acknowledged Mode (AM). The simulator includes one model for each of these entities

The RLC entities provide the RLC service interface to the upper PDCP layer and the MAC service interface to the lower MAC layer. The RLC entities use the PDCP service interface from the upper PDCP layer and the MAC service interface from the lower MAC layer.

Figure Implementation Model of PDCP, RLC and MAC entities and SAPs shows the implementation model of the RLC entities and its relationship with all the other entities and services in the protocol stack.

_images/lte-rlc-implementation-model.png

Implementation Model of PDCP, RLC and MAC entities and SAPs

Service Interfaces

RLC Service Interface

The RLC service interface is divided into two parts:

  • the RlcSapProvider part is provided by the RLC layer and used by the upper PDCP layer and

  • the RlcSapUser part is provided by the upper PDCP layer and used by the RLC layer.

Both the UM and the AM RLC entities provide the same RLC service interface to the upper PDCP layer.

RLC Service Primitives

The following list specifies which service primitives are provided by the RLC service interfaces:

  • RlcSapProvider::TransmitPdcpPdu

    • The PDCP entity uses this primitive to send a PDCP PDU to the lower RLC entity in the transmitter peer

  • RlcSapUser::ReceivePdcpPdu

    • The RLC entity uses this primitive to send a PDCP PDU to the upper PDCP entity in the receiver peer

MAC Service Interface

The MAC service interface is divided into two parts:

  • the MacSapProvider part is provided by the MAC layer and used by the upper RLC layer and

  • the MacSapUser part is provided by the upper RLC layer and used by the MAC layer.

MAC Service Primitives

The following list specifies which service primitives are provided by the MAC service interfaces:

  • MacSapProvider::TransmitPdu

    • The RLC entity uses this primitive to send a RLC PDU to the lower MAC entity in the transmitter peer

  • MacSapProvider::ReportBufferStatus

    • The RLC entity uses this primitive to report the MAC entity the size of pending buffers in the transmitter peer

  • MacSapUser::NotifyTxOpportunity

    • The MAC entity uses this primitive to notify the RLC entity a transmission opportunity

  • MacSapUser::ReceivePdu

    • The MAC entity uses this primitive to send an RLC PDU to the upper RLC entity in the receiver peer

AM RLC

The processing of the data transfer in the Acknowledge Mode (AM) RLC entity is explained in section 5.1.3 of [TS36322]. In this section we describe some details of the implementation of the RLC entity.

Buffers for the transmit operations

Our implementation of the AM RLC entity maintains 3 buffers for the transmit operations:

  • Transmission Buffer: it is the RLC SDU queue. When the AM RLC entity receives a SDU in the TransmitPdcpPdu service primitive from the upper PDCP entity, it enqueues it in the Transmission Buffer. We put a limit on the RLC buffer size and the LteRlc TxDrop trace source is called when a drop due to a full buffer occurs.

  • Transmitted PDUs Buffer: it is the queue of transmitted RLC PDUs for which an ACK/NACK has not been received yet. When the AM RLC entity sends a PDU to the MAC entity, it also puts a copy of the transmitted PDU in the Transmitted PDUs Buffer.

  • Retransmission Buffer: it is the queue of RLC PDUs which are considered for retransmission (i.e., they have been NACKed). The AM RLC entity moves this PDU to the Retransmission Buffer, when it retransmits a PDU from the Transmitted Buffer.

Calculation of the buffer size

The Transmission Buffer contains RLC SDUs. A RLC PDU is one or more SDU segments plus an RLC header. The size of the RLC header of one RLC PDU depends on the number of SDU segments the PDU contains.

The 3GPP standard (section 6.1.3.1 of [TS36321]) says clearly that, for the uplink, the RLC and MAC headers are not considered in the buffer size that is to be report as part of the Buffer Status Report. For the downlink, the behavior is not specified. Neither [FFAPI] specifies how to do it. Our RLC model works by assuming that the calculation of the buffer size in the downlink is done exactly as in the uplink, i.e., not considering the RLC and MAC header size.

We note that this choice affects the interoperation with the MAC scheduler, since, in response to the Notify_Tx_Opportunity service primitive, the RLC is expected to create a PDU of no more than the size requested by the MAC, including RLC overhead. Hence, unneeded fragmentation can occur if (for example) the MAC notifies a transmission exactly equal to the buffer size previously reported by the RLC. We assume that it is left to the Scheduler to implement smart strategies for the selection of the size of the transmission opportunity, in order to eventually avoid the inefficiency of unneeded fragmentation.

Concatenation and Segmentation

The AM RLC entity generates and sends exactly one RLC PDU for each transmission opportunity even if it is smaller than the size reported by the transmission opportunity. So for instance, if a STATUS PDU is to be sent, then only this PDU will be sent in that transmission opportunity.

The segmentation and concatenation for the SDU queue of the AM RLC entity follows the same philosophy as the same procedures of the UM RLC entity but there are new state variables (see [TS36322] section 7.1) only present in the AM RLC entity.

It is noted that, according to the 3GPP specs, there is no concatenation for the Retransmission Buffer.

Re-segmentation

The current model of the AM RLC entity does not support the re-segmentation of the retransmission buffer. Rather, the AM RLC entity just waits to receive a big enough transmission opportunity.

Unsupported features

We do not support the following procedures of [TS36322] :

  • “Send an indication of successful delivery of RLC SDU” (See section 5.1.3.1.1)

  • “Indicate to upper layers that max retransmission has been reached” (See section 5.2.1)

  • “SDU discard procedures” (See section 5.3)

  • “Re-establishment procedure” (See section 5.4)

We do not support any of the additional primitives of RLC SAP for AM RLC entity. In particular:

  • no SDU discard notified by PDCP

  • no notification of successful / failed delivery by AM RLC entity to PDCP entity

UM RLC

In this section we describe the implementation of the Unacknowledged Mode (UM) RLC entity.

Transmit operations in downlink

The transmit operations of the UM RLC are similar to those of the AM RLC previously described in Section Transmit operations in downlink, with the difference that, following the specifications of [TS36322], retransmission are not performed, and there are no STATUS PDUs.

Transmit operations in uplink

The transmit operations in the uplink are similar to those of the downlink, with the main difference that the Report_Buffer_Status is sent from the UE MAC to the MAC Scheduler in the eNB over the air using the control channel.

Calculation of the buffer size

The calculation of the buffer size for the UM RLC is done using the same approach of the AM RLC, please refer to section Calculation of the buffer size for the corresponding description.

TM RLC

In this section we describe the implementation of the Transparent Mode (TM) RLC entity.

Transmit operations in downlink

In the simulator, the TM RLC still provides to the upper layers the same service interface provided by the AM and UM RLC entities to the PDCP layer; in practice, this interface is used by an RRC entity (not a PDCP entity) for the transmission of RLC SDUs. This choice is motivated by the fact that the services provided by the TM RLC to the upper layers, according to [TS36322], is a subset of those provided by the UM and AM RLC entities to the PDCP layer; hence, we reused the same interface for simplicity.

The transmit operations in the downlink are performed as follows. When the Transmit_PDCP_PDU service primitive is called by the upper layers, the TM RLC does the following:

  • put the SDU in the Transmission Buffer

  • compute the size of the Transmission Buffer

  • call the Report_Buffer_Status service primitive of the eNB MAC entity

Afterwards, when the MAC scheduler decides that some data can be sent by the logical channel to which the TM RLC entity belongs, the MAC entity notifies it to the TM RLC entity by calling the Notify_Tx_Opportunity service primitive. Upon reception of this primitive, the TM RLC entity does the following:

  • if the TX opportunity has a size that is greater than or equal to the size of the head-of-line SDU in the Transmission Buffer

    • dequeue the head-of-line SDU from the Transmission Buffer

    • create one RLC PDU that contains entirely that SDU, without any RLC header

    • Call the Transmit_PDU primitive in order to send the RLC PDU to the MAC entity.

Transmit operations in uplink

The transmit operations in the uplink are similar to those of the downlink, with the main difference that a transmission opportunity can also arise from the assignment of the UL GRANT as part of the Random Access procedure, without an explicit Buffer Status Report issued by the TM RLC entity.

Calculation of the buffer size

As per the specifications [TS36322], the TM RLC does not add any RLC header to the PDUs being transmitted. Because of this, the buffer size reported to the MAC layer is calculated simply by summing the size of all packets in the transmission buffer, thus notifying to the MAC the exact buffer size.

SM RLC

In addition to the AM, UM and TM implementations that are modeled after the 3GPP specifications, a simplified RLC model is provided, which is called Saturation Mode (SM) RLC. This RLC model does not accept PDUs from any above layer (such as PDCP); rather, the SM RLC takes care of the generation of RLC PDUs in response to the notification of transmission opportunities notified by the MAC. In other words, the SM RLC simulates saturation conditions, i.e., it assumes that the RLC buffer is always full and can generate a new PDU whenever notified by the scheduler.

The SM RLC is used for simplified simulation scenarios in which only the LTE Radio model is used, without the EPC and hence without any IP networking support. We note that, although the SM RLC is an unrealistic traffic model, it still allows for the correct simulation of scenarios with multiple flows belonging to different (non real-time) QoS classes, in order to test the QoS performance obtained by different schedulers. This can be done since it is the task of the Scheduler to assign transmission resources based on the characteristics (e.g., Guaranteed Bit Rate) of each Radio Bearer, which are specified upon the definition of each Bearer within the simulation program.

As for schedulers designed to work with real-time QoS traffic that has delay constraints, the SM RLC is probably not an appropriate choice. This is because the absence of actual RLC SDUs (replaced by the artificial generation of Buffer Status Reports) makes it not possible to provide the Scheduler with meaningful head-of-line-delay information, which is often the metric of choice for the implementation of scheduling policies for real-time traffic flows. For the simulation and testing of such schedulers, it is advisable to use either the UM or the AM RLC models instead.

PDCP

PDCP Model Overview

The reference document for the specification of the PDCP entity is [TS36323]. With respect to this specification, the PDCP model implemented in the simulator supports only the following features:

  • transfer of data (user plane or control plane);

  • maintenance of PDCP SNs;

  • transfer of SN status (for use upon handover);

The following features are currently not supported:

  • header compression and decompression of IP data flows using the ROHC protocol;

  • in-sequence delivery of upper layer PDUs at re-establishment of lower layers;

  • duplicate elimination of lower layer SDUs at re-establishment of lower layers for radio bearers mapped on RLC AM;

  • ciphering and deciphering of user plane data and control plane data;

  • integrity protection and integrity verification of control plane data;

  • timer based discard;

  • duplicate discarding.

PDCP Service Interface

The PDCP service interface is divided into two parts:

  • the PdcpSapProvider part is provided by the PDCP layer and used by the upper layer and

  • the PdcpSapUser part is provided by the upper layer and used by the PDCP layer.

PDCP Service Primitives

The following list specifies which service primitives are provided by the PDCP service interfaces:

  • PdcpSapProvider::TransmitPdcpSdu

    • The RRC entity uses this primitive to send an RRC PDU to the lower PDCP entity in the transmitter peer

  • PdcpSapUser::ReceivePdcpSdu

    • The PDCP entity uses this primitive to send an RRC PDU to the upper RRC entity in the receiver peer

RRC

Features

The RRC model implemented in the simulator provides the following functionality:

  • generation (at the eNB) and interpretation (at the UE) of System Information (in particular the Master Information Block and, at the time of this writing, only System Information Block Type 1 and 2)

  • initial cell selection

  • RRC connection establishment procedure

  • RRC reconfiguration procedure, supporting the following use cases: + reconfiguration of the SRS configuration index + reconfiguration of the PHY TX mode (MIMO) + reconfiguration of UE measurements + data radio bearer setup + handover

  • RRC connection re-establishment, supporting the following use cases: + handover

Architecture

The RRC model is divided into the following components:

  • the RRC entities LteUeRrc and LteEnbRrc, which implement the state machines of the RRC entities respectively at the UE and the eNB;

  • the RRC SAPs LteUeRrcSapProvider, LteUeRrcSapUser, LteEnbRrcSapProvider, LteEnbRrcSapUser, which allow the RRC entities to send and receive RRC messages and information elmenents;

  • the RRC protocol classes LteUeRrcProtocolIdeal, LteEnbRrcProtocolIdeal, LteUeRrcProtocolReal, LteEnbRrcProtocolReal, which implement two different models for the transmission of RRC messages.

Additionally, the RRC components use various other SAPs in order to interact with the rest of the protocol stack. A representation of all the SAPs that are used is provided in the figures LTE radio protocol stack architecture for the UE on the data plane, LTE radio protocol stack architecture for the UE on the control plane, LTE radio protocol stack architecture for the eNB on the data plane and LTE radio protocol stack architecture for the eNB on the control plane.

UE RRC State Machine

In Figure UE RRC State Machine we represent the state machine as implemented in the RRC UE entity.

_images/lte-ue-rrc-states.png

UE RRC State Machine

All the states are transient, however, the UE in “CONNECTED_NORMALLY” state will only switch to the IDLE state if the downlink SINR is below a defined threshold, which would lead to radio link failure Radio Link Failure. One the other hand, the UE would not be able switch to IDLE mode due to a handover failure, as mentioned in X2.

ENB RRC State Machine

The eNB RRC maintains the state for each UE that is attached to the cell. From an implementation point of view, the state of each UE is contained in an instance of the UeManager class. The state machine is represented in Figure ENB RRC State Machine for each UE.

_images/lte-enb-rrc-states.png

ENB RRC State Machine for each UE

Initial Cell Selection

Initial cell selection is an IDLE mode procedure, performed by UE when it has not yet camped or attached to an eNodeB. The objective of the procedure is to find a suitable cell and attach to it to gain access to the cellular network.

It is typically done at the beginning of simulation, as depicted in Figure Sample runs of initial cell selection in UE and timing of related events below. The time diagram on the left side is illustrating the case where initial cell selection succeed on first try, while the diagram on the right side is for the case where it fails on the first try and succeed on the second try. The timing assumes the use of real RRC protocol model (see RRC protocol models) and no transmission error.

_images/lte-cell-selection-timeline.png

Sample runs of initial cell selection in UE and timing of related events

The functionality is based on 3GPP IDLE mode specifications, such as in [TS36300], [TS36304], and [TS36331]. However, a proper implementation of IDLE mode is still missing in the simulator, so we reserve several simplifying assumptions:

  • multiple carrier frequency is not supported;

  • multiple Public Land Mobile Network (PLMN) identities (i.e. multiple network operators) is not supported;

  • RSRQ measurements are not utilized;

  • stored information cell selection is not supported;

  • “Any Cell Selection” state and camping to an acceptable cell is not supported;

  • marking a cell as barred or reserved is not supported;

  • Idle cell reselection is not supported, hence it is not possible for UE to camp to a different cell after the initial camp has been placed; and

  • UE’s Closed Subscriber Group (CSG) white list contains only one CSG identity.

Also note that initial cell selection is only available for EPC-enabled simulations. LTE-only simulations must use the manual attachment method. See section Network Attachment of the User Documentation for more information on their differences in usage.

The next subsections cover different parts of initial cell selection, namely cell search, broadcast of system information, and cell selection evaluation.

Broadcast of System Information

System information blocks are broadcasted by eNodeB to UEs at predefined time intervals, adapted from Section 5.2.1.2 of [TS36331]. The supported system information blocks are:

  • Master Information Block (MIB)

    Contains parameters related to the PHY layer, generated during cell configuration and broadcasted every 10 ms at the beginning of radio frame as a control message.

  • System Information Block Type 1 (SIB1)

    Contains information regarding network access, broadcasted every 20 ms at the middle of radio frame as a control message. Not used in manual attachment method. UE must have decoded MIB before it can receive SIB1.

  • System Information Block Type 2 (SIB2)

    Contains UL- and RACH-related settings, scheduled to transmit via RRC protocol at 16 ms after cell configuration, and then repeats every 80 ms (configurable through LteEnbRrc::SystemInformationPeriodicity attribute. UE must be camped to a cell in order to be able to receive its SIB2.

Reception of system information is fundamental for UE to advance in its lifecycle. MIB enables the UE to increase the initial DL bandwidth of 6 RBs to the actual operating bandwidth of the network. SIB1 provides information necessary for cell selection evaluation (explained in the next section). And finally SIB2 is required before the UE is allowed to switch to CONNECTED state.

Cell Selection Evaluation

UE RRC reviews the measurement report produced in Cell Search and the cell access information provided by SIB1. Once both information is available for a specific cell, the UE triggers the evaluation process. The purpose of this process is to determine whether the cell is a suitable cell to camp to.

The evaluation process is a slightly simplified version of Section 5.2.3.2 of [TS36304]. It consists of the following criteria:

  • Rx level criterion; and

  • closed subscriber group (CSG) criterion.

The first criterion, Rx level, is based on the cell’s measured RSRP Q_{rxlevmeas}, which has to be higher than a required minimum Q_{rxlevmin} in order to pass the criterion:

Q_{rxlevmeas} - Q_{rxlevmin} > 0

where Q_{rxlevmin} is determined by each eNodeB and is obtainable by UE from SIB1.

The last criterion, CSG, is a combination of a true-or-false parameter called CSG indication and a simple number CSG identity. The basic rule is that UE shall not camp to eNodeB with a different CSG identity. But this rule is only enforced when CSG indication is valued as true. More details are provided in Section Network Attachment of the User Documentation.

When the cell passes all the above criteria, the cell is deemed as suitable. Then UE camps to it (IDLE_CAMPED_NORMALLY state).

After this, upper layer may request UE to enter CONNECTED mode. Please refer to section RRC connection establishment for details on this.

On the other hand, when the cell does not pass the CSG criterion, then the cell is labeled as acceptable (Section 10.1.1.1 [TS36300]). In this case, the RRC entity will tell the PHY entity to synchronize to the second strongest cell and repeat the initial cell selection procedure using that cell. As long as no suitable cell is found, the UE will repeat these steps while avoiding cells that have been identified as acceptable.

Radio Admission Control

Radio Admission Control is supported by having the eNB RRC reply to an RRC CONNECTION REQUEST message sent by the UE with either an RRC CONNECTION SETUP message or an RRC CONNECTION REJECT message, depending on whether the new UE is to be admitted or not. In the current implementation, the behavior is determined by the boolean attribute ns3::LteEnbRrc::AdmitRrcConnectionRequest. There is currently no Radio Admission Control algorithm that dynamically decides whether a new connection shall be admitted or not.

Radio Bearer Configuration

Some implementation choices have been made in the RRC regarding the setup of radio bearers:

  • three Logical Channel Groups (out of four available) are configured for uplink buffer status report purposes, according to the following policy:

    • LCG 0 is for signaling radio bearers

    • LCG 1 is for GBR data radio bearers

    • LCG 2 is for Non-GBR data radio bearers

UE RRC Measurements Model

UE RRC measurements support

The UE RRC entity provides support for UE measurements; in particular, it implements the procedures described in Section 5.5 of [TS36331], with the following simplifying assumptions:

  • only E-UTRA intra-frequency measurements are supported, which implies:

    • only one measurement object is used during the simulation;

    • measurement gaps are not needed to perform the measurements;

    • Event B1 and B2 are not implemented;

  • only reportStrongestCells purpose is supported, while reportCGI and reportStrongestCellsForSON purposes are not supported;

  • s-Measure is not supported;

  • carrier aggregation is now supported in the LTE module - Event A6 is not implemented;

  • speed dependent scaling of time-to-trigger (Section 5.5.6.2 of [TS36331]) is not supported.

Overall design

The model is based on the concept of UE measurements consumer, which is an entity that may request an eNodeB RRC entity to provide UE measurement reports. Consumers are, for example, Handover algorithm, which compute handover decision based on UE measurement reports. Test cases and user’s programs may also become consumers. Figure Relationship between UE measurements and its consumers depicts the relationship between these entities.

_images/ue-meas-consumer.png

Relationship between UE measurements and its consumers

The whole UE measurements function at the RRC level is divided into 4 major parts:

  1. Measurement configuration (handled by LteUeRrc::ApplyMeasConfig)

  2. Performing measurements (handled by LteUeRrc::DoReportUeMeasurements)

  3. Measurement report triggering (handled by LteUeRrc::MeasurementReportTriggering)

  4. Measurement reporting (handled by LteUeRrc::SendMeasurementReport)

The following sections will describe each of the parts above.

Measurement configuration

An eNodeB RRC entity configures UE measurements by sending the configuration parameters to the UE RRC entity. This set of parameters are defined within the MeasConfig Information Element (IE) of the RRC Connection Reconfiguration message (RRC connection reconfiguration).

The eNodeB RRC entity implements the configuration parameters and procedures described in Section 5.5.2 of [TS36331], with the following simplifying assumption:

  • configuration (i.e. addition, modification, and removal) can only be done before the simulation begins;

  • all UEs attached to the eNodeB will be configured the same way, i.e. there is no support for configuring specific measurement for specific UE; and

  • it is assumed that there is a one-to-one mapping between the PCI and the E-UTRAN Global Cell Identifier (EGCI). This is consistent with the PCI modeling assumptions described in UE PHY Measurements Model.

The eNodeB RRC instance here acts as an intermediary between the consumers and the attached UEs. At the beginning of simulation, each consumer provides the eNodeB RRC instance with the UE measurements configuration that it requires. After that, the eNodeB RRC distributes the configuration to attached UEs.

Users may customize the measurement configuration using several methods. Please refer to Section Configure UE measurements of the User Documentation for the description of these methods.

Performing measurements

UE RRC receives both RSRP and RSRQ measurements on periodical basis from UE PHY, as described in UE PHY Measurements Model. Layer 3 filtering will be applied to these received measurements. The implementation of the filtering follows Section 5.5.3.2 of [TS36331]:

F_n = (1 - a) \times F_{n-1} + a \times M_n

where:

  • M_n is the latest received measurement result from the physical layer;

  • F_n is the updated filtered measurement result;

  • F_{n-1} is the old filtered measurement result, where F_0 = M_1 (i.e. the first measurement is not filtered); and

  • a = (\frac{1}{2})^{\frac{k}{4}}, where k is the configurable filterCoefficent provided by the QuantityConfig;

k = 4 is the default value, but can be configured by setting the RsrpFilterCoefficient and RsrqFilterCoefficient attributes in LteEnbRrc.

Therefore k = 0 will disable Layer 3 filtering. On the other hand, past measurements can be granted more influence on the filtering results by using larger value of k.

Measurement reporting triggering

In this part, UE RRC will go through the list of active measurement configuration and check whether the triggering condition is fulfilled in accordance with Section 5.5.4 of [TS36331]. When at least one triggering condition from all the active measurement configuration is fulfilled, the measurement reporting procedure (described in the next subsection) will be initiated.

3GPP defines two kinds of triggerType: periodical and event-based. At the moment, only event-based criterion is supported. There are various events that can be selected, which are briefly described in the table below:

List of supported event-based triggering criteria

Name

Description

Event A1

Serving cell becomes better than threshold

Event A2

Serving cell becomes worse than threshold

Event A3

Neighbour becomes offset dB better than serving cell

Event A4

Neighbour becomes better than threshold

Event A5

Serving becomes worse than threshold1 AND neighbour becomes better than threshold2

Two main conditions to be checked in an event-based trigger are the entering condition and the leaving condition. More details on these two can be found in Section 5.5.4 of [TS36331].

An event-based trigger can be further configured by introducing hysteresis and time-to-trigger. Hysteresis (Hys) defines the distance between the entering and leaving conditions in dB. Similarly, time-to-trigger introduces delay to both entering and leaving conditions, but as a unit of time.

The periodical type of reporting trigger is not supported, but its behavior can be easily obtained by using an event-based trigger. This can be done by configuring the measurement in such a way that the entering condition is always fulfilled, for example, by setting the threshold of Event A1 to zero (the minimum level). As a result, the measurement reports will always be triggered at every certain interval, as determined by the reportInterval field within LteRrcSap::ReportConfigEutra, therefore producing the same behaviour as periodical reporting.

As a limitation with respect to 3GPP specifications, the current model does not support any cell-specific configuration. These configuration parameters are defined in measurement object. As a consequence, incorporating a list of black cells into the triggering process is not supported. Moreover, cell-specific offset (i.e., O_{cn} and O_{cp} in Event A3, A4, and A5) are not supported as well. The value equal to zero is always assumed in place of them.

Measurement reporting

This part handles the submission of measurement report from the UE RRC entity to the serving eNodeB entity via RRC protocol. Several simplifying assumptions have been adopted:

  • reportAmount is not applicable (i.e. always assumed to be infinite);

  • in measurement reports, the reportQuantity is always assumed to be BOTH, i.e., both RSRP and RSRQ are always reported, regardless of the triggerQuantity.

Handover

The RRC model supports UE mobility in CONNECTED mode by invoking the X2-based handover procedure. The model is intra-EUTRAN and intra-frequency, as based on Section 10.1.2.1 of [TS36300].

This section focuses on the process of triggering a handover. The handover execution procedure itself is covered in Section X2.

There are two ways to trigger the handover procedure:

  • explicitly (or manually) triggered by the simulation program by scheduling an execution of the method LteEnbRrc::SendHandoverRequest; or

  • automatically triggered by the eNodeB RRC entity based on UE measurements and according to the selected handover algorithm.

Section X2-based handover of the User Documentation provides some examples on using both explicit and automatic handover triggers in simulation. The next subsection will take a closer look on the automatic method, by describing the design aspects of the handover algorithm interface and the available handover algorithms.

Handover algorithm

Handover in 3GPP LTE has the following properties:

  • UE-assisted

    The UE provides input to the network in the form of measurement reports. This is handled by the UE RRC Measurements Model.

  • Network-controlled

    The network (i.e. the source eNodeB and the target eNodeB) decides when to trigger the handover and oversees its execution.

The handover algorithm operates at the source eNodeB and is responsible in making handover decisions in an “automatic” manner. It interacts with an eNodeB RRC instance via the Handover Management SAP interface. These relationships are illustrated in Figure Relationship between UE measurements and its consumers from the previous section.

The handover algorithm interface consists of the following methods:

  • AddUeMeasReportConfigForHandover

    (Handover Algorithm -> eNodeB RRC) Used by the handover algorithm to request measurement reports from the eNodeB RRC entity, by passing the desired reporting configuration. The configuration will be applied to all future attached UEs.

  • ReportUeMeas

    (eNodeB RRC -> Handover Algorithm) Based on the UE measurements configured earlier in AddUeMeasReportConfigForHandover, UE may submit measurement reports to the eNodeB. The eNodeB RRC entity uses the ReportUeMeas interface to forward these measurement reports to the handover algorithm.

  • TriggerHandover

    (Handover Algorithm -> eNodeB RRC) After examining the measurement reports (but not necessarily), the handover algorithm may declare a handover. This method is used to notify the eNodeB RRC entity about this decision, which will then proceed to commence the handover procedure.

One note for the AddUeMeasReportConfigForHandover. The method will return the measId (measurement identity) of the newly created measurement configuration. Typically a handover algorithm would store this unique number. It may be useful in the ReportUeMeas method, for example when more than one configuration has been requested and the handover algorithm needs to differentiate incoming reports based on the configuration that triggered them.

A handover algorithm is implemented by writing a subclass of the LteHandoverAlgorithm abstract superclass and implementing each of the above mentioned SAP interface methods. Users may develop their own handover algorithm this way, and then use it in any simulation by following the steps outlined in Section X2-based handover of the User Documentation.

Alternatively, users may choose to use one of the 3 built-in handover algorithms provided by the LTE module: no-op, A2-A4-RSRQ, and strongest cell handover algorithm. They are ready to be used in simulations or can be taken as an example of implementing a handover algorithm. Each of these built-in algorithms is covered in each of the following subsections.

No-op handover algorithm

The no-op handover algorithm (NoOpHandoverAlgorithm class) is the simplest possible implementation of handover algorithm. It basically does nothing, i.e., does not call any of the Handover Management SAP interface methods. Users may choose this handover algorithm if they wish to disable automatic handover trigger in their simulation.

A2-A4-RSRQ handover algorithm

The A2-A4-RSRQ handover algorithm provides the functionality of the default handover algorithm originally included in LENA M6 (ns-3.18), ported to the Handover Management SAP interface as the A2A4RsrqHandoverAlgorithm class.

As the name implies, the algorithm utilizes the Reference Signal Received Quality (RSRQ) measurements acquired from Event A2 and Event A4. Thus, the algorithm will add 2 measurement configuration to the corresponding eNodeB RRC instance. Their intended use are described as follows:

  • Event A2 (serving cell’s RSRQ becomes worse than threshold) is leveraged to indicate that the UE is experiencing poor signal quality and may benefit from a handover.

  • Event A4 (neighbour cell’s RSRQ becomes better than threshold) is used to detect neighbouring cells and acquire their corresponding RSRQ from every attached UE, which are then stored internally by the algorithm. By default, the algorithm configures Event A4 with a very low threshold, so that the trigger criteria are always true.

Figure A2-A4-RSRQ handover algorithm below summarizes this procedure.

_images/lte-legacy-handover-algorithm.png

A2-A4-RSRQ handover algorithm

Two attributes can be set to tune the algorithm behaviour:

  • ServingCellThreshold

    The threshold for Event A2, i.e. a UE must have an RSRQ lower than this threshold to be considered for a handover.

  • NeighbourCellOffset

    The offset that aims to ensure that the UE would receive better signal quality after the handover. A neighbouring cell is considered as a target cell for the handover only if its RSRQ is higher than the serving cell’s RSRQ by the amount of this offset.

The value of both attributes are expressed as RSRQ range (Section 9.1.7 of [TS36133]), which is an integer between 0 and 34, with 0 as the lowest RSRQ.

Strongest cell handover algorithm

The strongest cell handover algorithm, or also sometimes known as the traditional power budget (PBGT) algorithm, is developed using [Dimou2009] as reference. The idea is to provide each UE with the best possible Reference Signal Received Power (RSRP). This is done by performing a handover as soon as a better cell (i.e. with stronger RSRP) is detected.

Event A3 (neighbour cell’s RSRP becomes better than serving cell’s RSRP) is chosen to realize this concept. The A3RsrpHandoverAlgorithm class is the result of the implementation. Handover is triggered for the UE to the best cell in the measurement report.

A simulation which uses this algorithm is usually more vulnerable to ping-pong handover (consecutive handover to the previous source eNodeB within short period of time), especially when the Fading Model is enabled. This problem is typically tackled by introducing a certain delay to the handover. The algorithm does this by including hysteresis and time-to-trigger parameters (Section 6.3.5 of [TS36331]) to the UE measurements configuration.

Hysteresis (a.k.a. handover margin) delays the handover in regard of RSRP. The value is expressed in dB, ranges between 0 to 15 dB, and have a 0.5 dB accuracy, e.g., an input value of 2.7 dB is rounded to 2.5 dB.

On the other hand, time-to-trigger delays the handover in regard of time. 3GPP defines 16 valid values for time-to-trigger (all in milliseconds): 0, 40, 64, 80, 100, 128, 160, 256, 320, 480, 512, 640, 1024, 1280, 2560, and 5120.

The difference between hysteresis and time-to-trigger is illustrated in Figure Effect of hysteresis and time-to-trigger in strongest cell handover algorithm below, which is taken from the lena-x2-handover-measures example. It depicts the perceived RSRP of serving cell and a neighbouring cell by a UE which moves pass the border of the cells.

_images/lte-strongest-cell-handover-algorithm.png

Effect of hysteresis and time-to-trigger in strongest cell handover algorithm

By default, the algorithm uses a hysteresis of 3.0 dB and time-to-trigger of 256 ms. These values can be tuned through the Hysteresis and TimeToTrigger attributes of the A3RsrpHandoverAlgorithm class.

Neighbour Relation

LTE module supports a simplified Automatic Neighbour Relation (ANR) function. This is handled by the LteAnr class, which interacts with an eNodeB RRC instance through the ANR SAP interface.

Neighbour Relation Table

The ANR holds a Neighbour Relation Table (NRT), similar to the description in Section 22.3.2a of [TS36300]. Each entry in the table is called a Neighbour Relation (NR) and represents a detected neighbouring cell, which contains the following boolean fields:

  • No Remove

    Indicates that the NR shall not be removed from the NRT. This is true by default for user-provided NR and false otherwise.

  • No X2

    Indicates that the NR shall not use an X2 interface in order to initiate procedures towards the eNodeB parenting the target cell. This is false by default for user-provided NR, and true otherwise.

  • No HO

    Indicates that the NR shall not be used by the eNodeB for handover reasons. This is true in most cases, except when the NR is both user-provided and network-detected.

Each NR entry may have at least one of the following properties:

  • User-provided

    This type of NR is created as instructed by the simulation user. For example, a NR is created automatically upon a user-initiated establishment of X2 connection between 2 eNodeBs, e.g. as described in Section X2-based handover. Another way to create a user-provided NR is to call the AddNeighbourRelation function explicitly.

  • Network-detected

    This type of NR is automatically created during the simulation as a result of the discovery of a nearby cell.

In order to automatically create network-detected NR, ANR utilizes UE measurements. In other words, ANR is a consumer of UE measurements, as depicted in Figure Relationship between UE measurements and its consumers. RSRQ and Event A4 (neighbour becomes better than threshold) are used for the reporting configuration. The default Event A4 threshold is set to the lowest possible, i.e., maximum detection capability, but can be changed by setting the Threshold attribute of LteAnr class. Note that the A2-A4-RSRQ handover algorithm also utilizes a similar reporting configuration. Despite the similarity, when both ANR and this handover algorithm are active in the eNodeB, they use separate reporting configuration.

Also note that automatic setup of X2 interface is not supported. This is the reason why the No X2 and No HO fields are true in a network-detected but not user-detected NR.

Role of ANR in Simulation

The ANR SAP interface provides the means of communication between ANR and eNodeB RRC. Some interface functions are used by eNodeB RRC to interact with the NRT, as shown below:

  • AddNeighbourRelation

    (eNodeB RRC -> ANR) Add a new user-provided NR entry into the NRT.

  • GetNoRemove

    (eNodeB RRC -> ANR) Get the value of No Remove field of an NR entry of the given cell ID.

  • GetNoHo

    (eNodeB RRC -> ANR) Get the value of No HO field of an NR entry of the given cell ID.

  • GetNoX2

    (eNodeB RRC -> ANR) Get the value of No X2 field of an NR entry of the given cell ID.

Other interface functions exist to support the role of ANR as a UE measurements consumer, as listed below:

  • AddUeMeasReportConfigForAnr

    (ANR -> eNodeB RRC) Used by the ANR to request measurement reports from the eNodeB RRC entity, by passing the desired reporting configuration. The configuration will be applied to all future attached UEs.

  • ReportUeMeas

    (eNodeB RRC -> ANR) Based on the UE measurements configured earlier in AddUeMeasReportConfigForAnr, UE may submit measurement reports to the eNodeB. The eNodeB RRC entity uses the ReportUeMeas interface to forward these measurement reports to the ANR.

Please refer to the corresponding API documentation for LteAnrSap class for more details on the usage and the required parameters.

The ANR is utilized by the eNodeB RRC instance as a data structure to keep track of the situation of nearby neighbouring cells. The ANR also helps the eNodeB RRC instance to determine whether it is possible to execute a handover procedure to a neighbouring cell. This is realized by the fact that eNodeB RRC will only allow a handover procedure to happen if the NR entry of the target cell has both No HO and No X2 fields set to false.

ANR is enabled by default in every eNodeB instance in the simulation. It can be disabled by setting the AnrEnabled attribute in LteHelper class to false.

RRC sequence diagrams

In this section we provide some sequence diagrams that explain the most important RRC procedures being modeled.

RRC connection establishment

Figure Sequence diagram of the RRC Connection Establishment procedure shows how the RRC Connection Establishment procedure is modeled, highlighting the role of the RRC layer at both the UE and the eNB, as well as the interaction with the other layers.

_images/rrc-connection-establishment.png

Sequence diagram of the RRC Connection Establishment procedure

There are several timeouts related to this procedure, which are listed in the following Table Timers in RRC connection establishment procedure. If any of these timers expired, the RRC connection establishment procedure is terminated in failure. At the UE side, if T300 timer has expired a consecutive connEstFailCount times on the same cell it performs the cell selection again [TS36331]. Else, the upper layer (UE NAS) will immediately attempt to retry the procedure.

Timers in RRC connection establishment procedure

Name

Location

Timer starts

Timer stops

Default duration

When timer expired

Connection request timeout

eNodeB RRC

New UE context added

Receive RRC CONNECTION REQUEST

15 ms (Max)

Remove UE context

Connection timeout (T300 timer)

UE RRC

Send RRC CONNECTION REQUEST

Receive RRC CONNECTION SETUP or REJECT

100 ms

Reset UE MAC

Connection setup timeout

eNodeB RRC

Send RRC CONNECTION SETUP

Receive RRC CONNECTION SETUP COMPLETE

100 ms

Remove UE context

Connection rejected timeout

eNodeB RRC

Send RRC CONNECTION REJECT

Never

30 ms

Remove UE context

Note: The value of connection request timeout timer at the eNB RRC should not be higher than the T300 timer at UE RRC. It is to make sure that the UE context is already removed at the eNB, once the UE will perform cell selection upon reaching the connEstFailCount count. Moreover, at the time of writing this document the Cell Selection Evaluation does not include the Qoffset_{temp} parameter, thus, it is not applied while selecting the same cell again.

Counters in RRC connection establishment procedure

Name

Location

Msg

Monitored by

Default value

Limit not reached

Limit reached

ConnEstFailCount

eNB MAC

RachConfigCommon in SIB2, HO REQ and HO Ack

UE RRC

1

Increment the local counter. Invalided the prev SIB2 msg, and try random access with the same cell.

Reset the local counter and perform cell selection.

RRC connection reconfiguration

Figure Sequence diagram of the RRC Connection Reconfiguration procedure shows how the RRC Connection Reconfiguration procedure is modeled for the case where MobilityControlInfo is not provided, i.e., handover is not performed.

_images/rrc-connection-reconfiguration.png

Sequence diagram of the RRC Connection Reconfiguration procedure

Figure Sequence diagram of the RRC Connection Reconfiguration procedure for the handover case shows how the RRC Connection Reconfiguration procedure is modeled for the case where MobilityControlInfo is provided, i.e., handover is to be performed. As specified in [TS36331], After receiving the handover message, the UE attempts to access the target cell at the first available RACH occasion according to Random Access resource selection defined in [TS36321]_, i.e. the handover is asynchronous. Consequently, when allocating a dedicated preamble for the random access in the target cell, E-UTRA shall ensure it is available from the first RACH occasion the UE may use. Upon successful completion of the handover, the UE sends a message used to confirm the handover. Note that the random access procedure in this case is non-contention based, hence in a real LTE system it differs slightly from the one used in RRC connection established. Also note that the RA Preamble ID is signaled via the Handover Command included in the X2 Handover Request ACK message sent from the target eNB to the source eNB; in particular, the preamble is included in the RACH-ConfigDedicated IE which is part of MobilityControlInfo.

_images/rrc-connection-reconfiguration-handover.png

Sequence diagram of the RRC Connection Reconfiguration procedure for the handover case

RRC protocol models

As previously anticipated, we provide two different models for the transmission and reception of RRC messages: Ideal and Real. Each of them is described in one of the following subsections.

Ideal RRC protocol model

According to this model, implemented in the classes and LteUeRrcProtocolIdeal and LteEnbRrcProtocolIdeal, all RRC messages and information elements are transmitted between the eNB and the UE in an ideal fashion, without consuming radio resources and without errors. From an implementation point of view, this is achieved by passing the RRC data structure directly between the UE and eNB RRC entities, without involving the lower layers (PDCP, RLC, MAC, scheduler).

Real RRC protocol model

This model is implemented in the classes LteUeRrcProtocolReal and LteEnbRrcProtocolReal and aims at modeling the transmission of RRC PDUs as commonly performed in real LTE systems. In particular:

  • for every RRC message being sent, a real RRC PDUs is created following the ASN.1 encoding of RRC PDUs and information elements (IEs) specified in [TS36331]. Some simplification are made with respect to the IEs included in the PDU, i.e., only those IEs that are useful for simulation purposes are included. For a detailed list, please see the IEs defined in lte-rrc-sap.h and compare with [TS36331].

  • the encoded RRC PDUs are sent on Signaling Radio Bearers and are subject to the same transmission modeling used for data communications, thus including scheduling, radio resource consumption, channel errors, delays, retransmissions, etc.

Signaling Radio Bearer model

We now describe the Signaling Radio Bearer model that is used for the Real RRC protocol model.

  • SRB0 messages (over CCCH):

    • RrcConnectionRequest: in real LTE systems, this is an RLC TM SDU sent over resources specified in the UL Grant in the RAR (not in UL DCIs); the reason is that C-RNTI is not known yet at this stage. In the simulator, this is modeled as a real RLC TM RLC PDU whose UL resources are allocated by the scheduler upon call to SCHED_DL_RACH_INFO_REQ.

    • RrcConnectionSetup: in the simulator this is implemented as in real LTE systems, i.e., with an RLC TM SDU sent over resources indicated by a regular UL DCI, allocated with SCHED_DL_RLC_BUFFER_REQ triggered by the RLC TM instance that is mapped to LCID 0 (the CCCH).

  • SRB1 messages (over DCCH):

    • All the SRB1 messages modeled in the simulator (e.g., RrcConnectionCompleted) are implemented as in real LTE systems, i.e., with a real RLC SDU sent over RLC AM using DL resources allocated via Buffer Status Reports. See the RLC model documentation for details.

  • SRB2 messages (over DCCH):

    • According to [TS36331], “SRB1 is for RRC messages (which may include a piggybacked NAS message) as well as for NAS messages prior to the establishment of SRB2, all using DCCH logical channel”, whereas “SRB2 is for NAS messages, using DCCH logical channel” and “SRB2 has a lower-priority than SRB1 and is always configured by E-UTRAN after security activation”. Modeling security-related aspects is not a requirement of the LTE simulation model, hence we always use SRB1 and never activate SRB2.

ASN.1 encoding of RRC IE’s

The messages defined in RRC SAP, common to all Ue/Enb SAP Users/Providers, are transported in a transparent container to/from a Ue/Enb. The encoding format for the different Information Elements are specified in [TS36331], using ASN.1 rules in the unaligned variant. The implementation in Ns3/Lte has been divided in the following classes:

  • Asn1Header : Contains the encoding / decoding of basic ASN types

  • RrcAsn1Header : Inherits Asn1Header and contains the encoding / decoding of common IE’s defined in [TS36331]

  • Rrc specific messages/IEs classes : A class for each of the messages defined in RRC SAP header

Asn1Header class - Implementation of base ASN.1 types

This class implements the methods to Serialize / Deserialize the ASN.1 types being used in [TS36331], according to the packed encoding rules in ITU-T X.691. The types considered are:

  • Boolean : a boolean value uses a single bit (1=true, 0=false).

  • Integer : a constrained integer (with min and max values defined) uses the minimum amount of bits to encode its range (max-min+1).

  • Bitstring : a bistring will be copied bit by bit to the serialization buffer.

  • Octetstring : not being currently used.

  • Sequence : the sequence generates a preamble indicating the presence of optional and default fields. It also adds a bit indicating the presence of extension marker.

  • Sequence…Of : the sequence…of type encodes the number of elements of the sequence as an integer (the subsequent elements will need to be encoded afterwards).

  • Choice : indicates which element among the ones in the choice set is being encoded.

  • Enumeration : is serialized as an integer indicating which value is used, among the ones in the enumeration, with the number of elements in the enumeration as upper bound.

  • Null : the null value is not encoded, although its serialization function is defined to provide a clearer map between specification and implementation.

The class inherits from ns-3 Header, but Deserialize() function is declared pure virtual, thus inherited classes having to implement it. The reason is that deserialization will retrieve the elements in RRC messages, each of them containing different information elements.

Additionally, it has to be noted that the resulting byte length of a specific type/message can vary, according to the presence of optional fields, and due to the optimized encoding. Hence, the serialized bits will be processed using PreSerialize() function, saving the result in m_serializationResult Buffer. As the methods to read/write in a ns3 buffer are defined in a byte basis, the serialization bits are stored into m_serializationPendingBits attribute, until the 8 bits are set and can be written to buffer iterator. Finally, when invoking Serialize(), the contents of the m_serializationResult attribute will be copied to Buffer::Iterator parameter

RrcAsn1Header : Common IEs

As some Information Elements are being used for several RRC messages, this class implements the following common IE’s:

  • SrbToAddModList

  • DrbToAddModList

  • LogicalChannelConfig

  • RadioResourceConfigDedicated

  • PhysicalConfigDedicated

  • SystemInformationBlockType1

  • SystemInformationBlockType2

  • RadioResourceConfigCommonSIB

Rrc specific messages/IEs classes

The following RRC SAP have been implemented:

  • RrcConnectionRequest

  • RrcConnectionSetup

  • RrcConnectionSetupCompleted

  • RrcConnectionReconfiguration

  • RrcConnectionReconfigurationCompleted

  • HandoverPreparationInfo

  • RrcConnectionReestablishmentRequest

  • RrcConnectionReestablishment

  • RrcConnectionReestablishmentComplete

  • RrcConnectionReestablishmentReject

  • RrcConnectionRelease

NAS

The focus of the LTE-EPC model is on the NAS Active state, which corresponds to EMM Registered, ECM connected, and RRC connected. Because of this, the following simplifications are made:

  • EMM and ECM are not modeled explicitly; instead, the NAS entity at the UE will interact directly with the MME to perform actions that are equivalent (with gross simplifications) to taking the UE to the states EMM Connected and ECM Connected;

  • the NAS also takes care of multiplexing uplink data packets coming from the upper layers into the appropriate EPS bearer by using the Traffic Flow Template classifier (TftClassifier).

  • the NAS does not support PLMN and CSG selection

  • the NAS does not support any location update/paging procedure in idle mode

Figure Sequence diagram of the attach procedure shows how the simplified NAS model implements the attach procedure. Note that both the default and eventual dedicated EPS bearers are activated as part of this procedure.

_images/nas-attach.png

Sequence diagram of the attach procedure

S1, S5 and S11

S1-U and S5 (user plane)

The S1-U and S5 interfaces are modeled in a realistic way by encapsulating data packets over GTP/UDP/IP, as done in real LTE-EPC systems. The corresponding protocol stack is shown in Figure LTE-EPC data plane protocol stack. As shown in the figure, there are two different layers of IP networking. The first one is the end-to-end layer, which provides end-to-end connectivity to the users; this layer involves the UEs, the PGW and the remote host (including eventual internet routers and hosts in between), but does not involve the eNB and the SGW. In this version of LTE, the EPC supports both IPv4 and IPv6 type users. The 3GPP unique 64 bit IPv6 prefix allocation process for each UE and PGW is followed here. Each EPC is assigned a unique 16 bit IPv4 and a 48 bit IPv6 network address from the pool of 7.0.0.0/8 and 7777:f00d::/32 respectively. In the end-to-end IP connection between UE and PGW, all addresses are configured using these prefixes. The PGW’s address is used by all UEs as the gateway to reach the internet.

The second layer of IP networking is the EPC local area network. This involves all eNB nodes, SGW nodes and PGW nodes. This network is implemented as a set of point-to-point links which connect each eNB with its corresponding SGW node and a point-to-point link which connect each SGW node with its corresponding PGW node; thus, each SGW has a set of point-to-point devices, each providing connectivity to a different eNB. By default, a 10.x.y.z/30 subnet is assigned to each point-to-point link (a /30 subnet is the smallest subnet that allows for two distinct host addresses).

As specified by 3GPP, the end-to-end IP communications is tunneled over the local EPC IP network using GTP/UDP/IP. In the following, we explain how this tunneling is implemented in the EPC model. The explanation is done by discussing the end-to-end flow of data packets.

_images/epc-data-flow-dl-with-split.png

Data flow in the downlink between the internet and the UE

To begin with, we consider the case of the downlink, which is depicted in Figure Data flow in the downlink between the internet and the UE. Downlink IPv4/IPv6 packets are generated from a generic remote host, and addressed to one of the UE device. Internet routing will take care of forwarding the packet to the generic NetDevice of the PGW node which is connected to the internet (this is the Gi interface according to 3GPP terminology). The PGW has a VirtualNetDevice which is assigned the base IPv4 address of the EPC network; hence, static routing rules will cause the incoming packet from the internet to be routed through this VirtualNetDevice. In case of IPv6 address as destination, a manual route towards the VirtualNetDevice is inserted in the routing table, containing the 48 bit IPv6 prefix from which all the IPv6 addresses of the UEs and PGW are configured. Such device starts the GTP/UDP/IP tunneling procedure, by forwarding the packet to a dedicated application in the PGW node which is called EpcPgwApplication. This application does the following operations:

  1. it determines the SGW node to which it must route the traffic for this UE, by looking at the IP destination address (which is the address of the UE);

  2. it classifies the packet using Traffic Flow Templates (TFTs) to identify to which EPS Bearer it belongs. EPS bearers have a one-to-one mapping to S5 Bearers, so this operation returns the GTP-U Tunnel Endpoint Identifier (TEID) to which the packet belongs;

  3. it adds the corresponding GTP-U protocol header to the packet;

  4. finally, it sends the packet over a UDP socket to the S5 point-to-point NetDevice, addressed to the appropriate SGW.

As a consequence, the end-to-end IP packet with newly added IP, UDP and GTP headers is sent through one of the S5 links to the SGW, where it is received and delivered locally (as the destination address of the outermost IP header matches the SGW IP address). The local delivery process will forward the packet, via an UDP socket, to a dedicated application called EpcSgwApplication. This application then performs the following operations:

  1. it determines the eNB node to which the UE is attached, by looking at the S5 TEID;

  2. it maps the S5 TEID to get the S1 TEID. EPS bearers have a one-to-one mapping to S1-U Bearers, so this operation returns the S1 GTP-U Tunnel Endpoint Identifier (TEID) to which the packet belongs;

  3. it adds a new GTP-U protocol header to the packet;

  4. finally, it sends the packet over a UDP socket to the S1-U point-to-point NetDevice, addressed to the eNB to which the UE is attached.

Finally, the end-to-end IP packet with newly added IP, UDP and GTP headers is sent through one of the S1 links to the eNB, where it is received and delivered locally (as the destination address of the outermost IP header matches the eNB IP address). The local delivery process will forward the packet, via an UDP socket, to a dedicated application called EpcEnbApplication. This application then performs the following operations:

  1. it removes the GTP header and retrieves the S1 TEID which is contained in it;

  2. leveraging on the one-to-one mapping between S1-U bearers and Radio Bearers (which is a 3GPP requirement), it determines the Bearer ID (BID) to which the packet belongs;

  3. it records the BID in a dedicated tag called EpsBearerTag, which is added to the packet;

  4. it forwards the packet to the LteEnbNetDevice of the eNB node via a raw packet socket

Note that, at this point, the outmost header of the packet is the end-to-end IP header, since the IP/UDP/GTP headers of the S1 protocol stack have already been stripped. Upon reception of the packet from the EpcEnbApplication, the LteEnbNetDevice will retrieve the BID from the EpsBearerTag, and based on the BID will determine the Radio Bearer instance (and the corresponding PDCP and RLC protocol instances) which are then used to forward the packet to the UE over the LTE radio interface. Finally, the LteUeNetDevice of the UE will receive the packet, and delivery it locally to the IP protocol stack, which will in turn delivery it to the application of the UE, which is the end point of the downlink communication.

_images/epc-data-flow-ul-with-split.png

Data flow in the uplink between the UE and the internet

The case of the uplink is depicted in Figure Data flow in the uplink between the UE and the internet. Uplink IP packets are generated by a generic application inside the UE, and forwarded by the local TCP/IP stack to the LteUeNetDevice of the UE. The LteUeNetDevice then performs the following operations:

  1. it classifies the packet using TFTs and determines the Radio Bearer to which the packet belongs (and the corresponding RBID);

  2. it identifies the corresponding PDCP protocol instance, which is the entry point of the LTE Radio Protocol stack for this packet;

  3. it sends the packet to the eNB over the LTE Radio Protocol stack.

The eNB receives the packet via its LteEnbNetDevice. Since there is a single PDCP and RLC protocol instance for each Radio Bearer, the LteEnbNetDevice is able to determine the BID of the packet. This BID is then recorded onto an EpsBearerTag, which is added to the packet. The LteEnbNetDevice then forwards the packet to the EpcEnbApplication via a raw packet socket.

Upon receiving the packet, the EpcEnbApplication performs the following operations:

  1. it retrieves the BID from the EpsBearerTag in the packet;

  2. it determines the corresponding EPS Bearer instance and GTP-U TEID by leveraging on the one-to-one mapping between S1-U bearers and Radio Bearers;

  3. it adds a GTP-U header on the packet, including the TEID determined previously;

  4. it sends the packet to the SGW node via the UDP socket connected to the S1-U point-to-point net device.

At this point, the packet contains the S1-U IP, UDP and GTP headers in addition to the original end-to-end IP header. When the packet is received by the corresponding S1-U point-to-point NetDevice of the SGW node, it is delivered locally (as the destination address of the outmost IP header matches the address of the point-to-point net device). The local delivery process will forward the packet to the EpcSgwApplication via the corresponding UDP socket. The EpcSgwApplication then perfoms the following operations:

  1. it removes the GTP header and retrieves the S1-U TEID;

  2. it maps the S1-U TEID to get the S5 TEID to which the packet belongs;

  3. it determines the PGW to which it must send the packet from the TEID mapping;

  4. it add a new GTP-U protocol header to the packet;

  5. finally, it sends the packet over a UDP socket to the S5 point-to-point NetDevice, addressed to the corresponding PGW.

At this point, the packet contains the S5 IP, UDP and GTP headers in addition to the original end-to-end IP header. When the packet is received by the corresponding S5 point-to-point NetDevice of the PGW node, it is delivered locally (as the destination address of the outmost IP header matches the address of the point-to-point net device). The local delivery process will forward the packet to the EpcPgwApplication via the corresponding UDP socket. The EpcPgwApplication then removes the GTP header and forwards the packet to the VirtualNetDevice. At this point, the outmost header of the packet is the end-to-end IP header. Hence, if the destination address within this header is a remote host on the internet, the packet is sent to the internet via the corresponding NetDevice of the PGW. In the event that the packet is addressed to another UE, the IP stack of the PGW will redirect the packet again to the VirtualNetDevice, and the packet will go through the downlink delivery process in order to reach its destination UE.

Note that the EPS Bearer QoS is not enforced on the S1-U and S5 links, it is assumed that the overprovisioning of the link bandwidth is sufficient to meet the QoS requirements of all bearers.

S1AP

The S1-AP interface provides control plane interaction between the eNB and the MME. In the simulator, this interface is modeled in a realistic fashion transmitting the encoded S1AP messages and information elements specified in [TS36413] on the S1-MME link.

The S1-AP primitives that are modeled are:

  • INITIAL UE MESSAGE

  • INITIAL CONTEXT SETUP REQUEST

  • INITIAL CONTEXT SETUP RESPONSE

  • PATH SWITCH REQUEST

  • PATH SWITCH REQUEST ACKNOWLEDGE

S5 and S11

The S5 interface provides control plane interaction between the SGW and the PGW. The S11 interface provides control plane interaction between the SGw and the MME. Both interfaces use the GPRS Tunneling Protocol (GTPv2-C) to tunnel signalling messages [TS29274] and use UDP as transport protocol. In the simulator, these interfaces and protocol are modeled in a realistic fashion transmitting the encoded GTP-C messages.

The GTPv2-C primitives that are modeled are:

  • CREATE SESSION REQUEST

  • CREATE SESSION RESPONSE

  • MODIFY BEARER REQUEST

  • MODIFY BEARER RESPONSE

  • DELETE SESSION REQUEST

  • DELETE SESSION RESPONSE

  • DELETE BEARER COMMAND

  • DELETE BEARER REQUEST

  • DELETE BEARER RESPONSE

Of these primitives, the first two are used upon initial UE attachment for the establishment of the S1-U and S5 bearers. Section NAS shows the implementation of the attach procedure. The other primitives are used during the handover to switch the S1-U bearers from the source eNB to the target eNB as a consequence of the reception by the MME of a PATH SWITCH REQUEST S1-AP message.

X2

The X2 interface interconnects two eNBs [TS36420]. From a logical point of view, the X2 interface is a point-to-point interface between the two eNBs. In a real E-UTRAN, the logical point-to-point interface should be feasible even in the absence of a physical direct connection between the two eNBs. In the X2 model implemented in the simulator, the X2 interface is a point-to-point link between the two eNBs. A point-to-point device is created in both eNBs and the two point-to-point devices are attached to the point-to-point link.

For a representation of how the X2 interface fits in the overall architecture of the LENA simulation model, the reader is referred to the figure Overview of the LTE-EPC simulation model.

The X2 interface implemented in the simulator provides detailed implementation of the following elementary procedures of the Mobility Management functionality [TS36423]:

  • Handover Request procedure

  • Handover Request Acknowledgement procedure

  • SN Status Transfer procedure

  • UE Context Release procedure

These procedures are involved in the X2-based handover. You can find the detailed description of the handover in section 10.1.2.1 of [TS36300]. We note that the simulator model currently supports only the seamless handover as defined in Section 2.6.3.1 of [Sesia2009]; in particular, lossless handover as described in Section 2.6.3.2 of [Sesia2009] is not supported at the time of this writing.

Figure Sequence diagram of the X2-based handover below shows the interaction of the entities of the X2 model in the simulator. The shaded labels indicate the moments when the UE or eNodeB transition to another RRC state.

_images/lte-epc-x2-handover-seq-diagram.png

Sequence diagram of the X2-based handover

The figure also shows two timers within the handover procedure: the handover leaving timer is maintained by the source eNodeB, while the handover joining timer by the target eNodeB. The duration of the timers can be configured in the HandoverLeavingTimeoutDuration and HandoverJoiningTimeoutDuration attributes of the respective LteEnbRrc instances. When one of these timers expire, the handover procedure is considered as failed.

However, there is no proper handling of handover failure in the current version of LTE module. Users should tune the simulation properly in order to avoid handover failure, otherwise unexpected behaviour may occur. Please refer to Section Tuning simulation with handover of the User Documentation for some tips regarding this matter.

The X2 model is an entity that uses services from:

  • the X2 interfaces,

    • They are implemented as Sockets on top of the point-to-point devices.

    • They are used to send/receive X2 messages through the X2-C and X2-U interfaces (i.e. the point-to-point device attached to the point-to-point link) towards the peer eNB.

  • the S1 application.

    • Currently, it is the EpcEnbApplication.

    • It is used to get some information needed for the Elementary Procedures of the X2 messages.

and it provides services to:

  • the RRC entity (X2 SAP)

    • to send/receive RRC messages. The X2 entity sends the RRC message as a transparent container in the X2 message. This RRC message is sent to the UE.

Figure Implementation Model of X2 entity and SAPs shows the implementation model of the X2 entity and its relationship with all the other entities and services in the protocol stack.

_images/lte-epc-x2-entity-saps.png

Implementation Model of X2 entity and SAPs

The RRC entity manages the initiation of the handover procedure. This is done in the Handover Management submodule of the eNB RRC entity. The target eNB may perform some Admission Control procedures. This is done in the Admission Control submodule. Initially, this submodule will accept any handover request.

X2 interfaces

The X2 model contains two interfaces:

  • the X2-C interface. It is the control interface and it is used to send the X2-AP PDUs (i.e. the elementary procedures).

  • the X2-U interface. It is used to send the bearer data when there is DL forwarding.

Figure X2 interface protocol stacks shows the protocol stacks of the X2-U interface and X2-C interface modeled in the simulator.

_images/lte-epc-x2-interface.png

X2 interface protocol stacks

X2-C

The X2-C interface is the control part of the X2 interface and it is used to send the X2-AP PDUs (i.e. the elementary procedures).

In the original X2 interface control plane protocol stack, SCTP is used as the transport protocol but currently, the SCTP protocol is not modeled in the ns-3 simulator and its implementation is out-of-scope of the project. The UDP protocol is used as the datagram oriented protocol instead of the SCTP protocol.

X2-U

The X2-U interface is used to send the bearer data when there is DL forwarding during the execution of the X2-based handover procedure. Similarly to what done for the S1-U interface, data packets are encapsulated over GTP/UDP/IP when being sent over this interface. Note that the EPS Bearer QoS is not enforced on the X2-U links, it is assumed that the overprovisioning of the link bandwidth is sufficient to meet the QoS requirements of all bearers.

X2 Service Interface

The X2 service interface is used by the RRC entity to send and receive messages of the X2 procedures. It is divided into two parts:

  • the EpcX2SapProvider part is provided by the X2 entity and used by the RRC entity and

  • the EpcX2SapUser part is provided by the RRC entity and used by the RRC enity.

The primitives that are supported in our X2-C model are described in the following subsections.

X2-C primitives for handover execution

The following primitives are used for the X2-based handover:

  • HANDOVER REQUEST

  • HANDOVER REQUEST ACK

  • HANDOVER PREPARATION FAILURE

  • SN STATUS STRANSFER

  • UE CONTEXT RELEASE

all the above primitives are used by the currently implemented RRC model during the preparation and execution of the handover procedure. Their usage interacts with the RRC state machine; therefore, they are not meant to be used for code customization, at least unless it is desired to modify the RRC state machine.

X2-C SON primitives

The following primitives can be used to implement Self-Organized Network (SON) functionalities:

  • LOAD INFORMATION

  • RESOURCE STATUS UPDATE

note that the current RRC model does not actually use these primitives, they are included in the model just to make it possible to develop SON algorithms included in the RRC logic that make use of them.

As a first example, we show here how the load information primitive can be used. We assume that the LteEnbRrc has been modified to include the following new member variables:

std::vector<EpcX2Sap::UlInterferenceOverloadIndicationItem>
  m_currentUlInterferenceOverloadIndicationList;
std::vector <EpcX2Sap::UlHighInterferenceInformationItem>
  m_currentUlHighInterferenceInformationList;
EpcX2Sap::RelativeNarrowbandTxBand m_currentRelativeNarrowbandTxBand;

for a detailed description of the type of these variables, we suggest to consult the file epc-x2-sap.h, the corresponding doxygen documentation, and the references therein to the relevant sections of 3GPP TS 36.423. Now, assume that at run time these variables have been set to meaningful values following the specifications just mentioned. Then, you can add the following code in the LteEnbRrc class implementation in order to send a load information primitive:

EpcX2Sap::CellInformationItem cii;
cii.sourceCellId = m_cellId;
cii.ulInterferenceOverloadIndicationList = m_currentUlInterferenceOverloadIndicationList;
cii.ulHighInterferenceInformationList = m_currentUlHighInterferenceInformationList;
cii.relativeNarrowbandTxBand = m_currentRelativeNarrowbandTxBand;

EpcX2Sap::LoadInformationParams params;
params.targetCellId = cellId;
params.cellInformationList.push_back (cii);
m_x2SapProvider->SendLoadInformation (params);

The above code allows the source eNB to send the message. The method LteEnbRrc::DoRecvLoadInformation will be called when the target eNB receives the message. The desired processing of the load information should therefore be implemented within that method.

In the following second example we show how the resource status update primitive is used. We assume that the LteEnbRrc has been modified to include the following new member variable:

EpcX2Sap::CellMeasurementResultItem m_cmri;

similarly to before, we refer to epc-x2-sap.h and the references therein for detailed information about this variable type. Again, we assume that the variable has been already set to a meaningful value. Then, you can add the following code in order to send a resource status update:

EpcX2Sap::ResourceStatusUpdateParams params;
params.targetCellId = cellId;
params.cellMeasurementResultList.push_back (m_cmri);
m_x2SapProvider->SendResourceStatusUpdate (params);

The method eEnbRrc::DoRecvResourceStatusUpdate will be called when the target eNB receives the resource status update message. The desired processing of this message should therefore be implemented within that method.

Finally, we note that the setting and processing of the appropriate values for the variable passed to the above described primitives is deemed to be specific of the SON algorithm being implemented, and hence is not covered by this documentation.

Unsupported primitives

Mobility Robustness Optimization primitives such as Radio Link Failure indication and Handover Report are not supported at this stage.

S11

The S11 interface provides control plane interaction between the SGW and the MME using the GTPv2-C protocol specified in [TS29274]. In the simulator, this interface is modeled in an ideal fashion, with direct interaction between the SGW and the MME objects, without actually implementing the encoding of the messages and without actually transmitting any PDU on any link.

The S11 primitives that are modeled are:

  • CREATE SESSION REQUEST

  • CREATE SESSION RESPONSE

  • MODIFY BEARER REQUEST

  • MODIFY BEARER RESPONSE

Of these primitives, the first two are used upon initial UE attachment for the establishment of the S1-U bearers; the other two are used during handover to switch the S1-U bearers from the source eNB to the target eNB as a consequence of the reception by the MME of a PATH SWITCH REQUEST S1-AP message.

Power Control

This section describes the ns-3 implementation of Downlink and Uplink Power Control.

Fractional Frequency Reuse

Overview

This section describes the ns-3 support for Fractional Frequency Reuse algorithms. All implemented algorithms are described in [ASHamza2013]. Currently 7 FR algorithms are implemented:

  • ns3::LteFrNoOpAlgorithm

  • ns3::LteFrHardAlgorithm

  • ns3::LteFrStrictAlgorithm

  • ns3::LteFrSoftAlgorithm

  • ns3::LteFfrSoftAlgorithm

  • ns3::LteFfrEnhancedAlgorithm

  • ns3::LteFfrDistributedAlgorithm

New LteFfrAlgorithm class was created and it is a abstract class for Frequency Reuse algorithms implementation. Also, two new SAPs between FR-Scheduler and FR-RRC were added.

_images/lte-ffr-scheduling.png

Sequence diagram of Scheduling with FR algorithm

Figure Sequence diagram of Scheduling with FR algorithm shows the sequence diagram of scheduling process with FR algorithm. In the beginning of scheduling process, scheduler asks FR entity for available RBGs. According to implementation FR returns all RBGs available in cell or filter them based on its policy. Then when trying to assign some RBG to UE, scheduler asks FR entity if this RBG is allowed for this UE. When FR returns true, scheduler can assign this RBG to this UE, if not scheduler is checking another RBG for this UE. Again, FR response depends on implementation and policy applied to UE.

Supported FR algorithms

No Frequency Reuse

The NoOp FR algorithm (LteFrNoOpAlgorithm class) is implementation of Full Frequency Reuse scheme, that means no frequency partitioning is performed between eNBs of the same network (frequency reuse factor, FRF equals 1). eNBs uses entire system bandwidth and transmit with uniform power over all RBGs. It is the simplest scheme and is the basic way of operating an LTE network. This scheme allows for achieving the high peak data rate. But from the other hand, due to heavy interference levels from neighbouring cells, cell-edge users performance is greatly limited.

Figure Full Frequency Reuse scheme below presents frequency and power plan for Full Frequency Reuse scheme.

_images/fr-full-frequency-reuse-scheme.png

Full Frequency Reuse scheme

In ns-3, the NoOp FR algorithm always allows scheduler to use full bandwidth and allows all UEs to use any RBG. It simply does nothing new (i.e. it does not limit eNB bandwidth, FR algorithm is disabled), it is the simplest implementation of FrAlgorithm class and is installed in eNb by default.

Hard Frequency Reuse

The Hard Frequency Reuse algorithm provides the simplest scheme which allows to reduce inter-cell interference level. In this scheme whole frequency bandwidth is divided into few (typically 3, 4, or 7) disjoint sub-bands. Adjacent eNBs are allocated with different sub-band. Frequency reuse factor equals the number of sub-bands. This scheme allows to significantly reduce ICI at the cell edge, so the performance of cell-users is improved. But due to the fact, that each eNB uses only one part of whole bandwidth, peak data rate level is also reduced by the factor equal to the reuse factor.

Figure Hard Frequency Reuse scheme below presents frequency and power plan for Hard Frequency Reuse scheme.

_images/fr-hard-frequency-reuse-scheme.png

Hard Frequency Reuse scheme

In our implementation, the Hard FR algorithm has only vector of RBGs available for eNB and pass it to MAC Scheduler during scheduling functions. When scheduler ask, if RBG is allowed for specific UE it always return true.

Strict Frequency Reuse

Strict Frequency Reuse scheme is combination of Full and Hard Frequency Reuse schemes. It consists of dividing the system bandwidth into two parts which will have different frequency reuse. One common sub-band of the system bandwidth is used in each cell interior (frequency reuse-1), while the other part of the bandwidth is divided among the neighboring eNBs as in hard frequency reuse (frequency reuse-N, N>1), in order to create one sub-band with a low inter-cell interference level in each sector. Center UEs will be granted with the fully-reused frequency chunks, while cell-edge UEs with orthogonal chunks. It means that interior UEs from one cell do not share any spectrum with edge UEs from second cell, which reduces interference for both. As can be noticed, Strict FR requires a total of N + 1 sub-bands, and allows to achieve RFR in the middle between 1 and 3.

Figure Strict Frequency Reuse scheme below presents frequency and power plan for Strict Frequency Reuse scheme with a cell-edge reuse factor of N = 3.

_images/fr-strict-frequency-reuse-scheme.png

Strict Frequency Reuse scheme

In our implementation, Strict FR algorithm has two maps, one for each sub-band. If UE can be served within private sub-band, its RNTI is added to m_privateSubBandUe map. If UE can be served within common sub-band, its RNTI is added to m_commonSubBandUe map. Strict FR algorithm needs to decide within which sub-band UE should be served. It uses UE measurements provided by RRB and compare them with signal quality threshold (this parameter can be easily tuned by attribute mechanism). Threshold has influence on interior to cell radius ratio.

Soft Frequency Reuse

In Soft Frequency Reuse (SFR) scheme each eNb transmits over the entire system bandwidth, but there are two sub-bands, within UEs are served with different power level. Since cell-center UEs share the bandwidth with neighboring cells, they usually transmit at lower power level than the cell-edge UEs. SFR is more bandwidth efficient than Strict FR, because it uses entire system bandwidth, but it also results in more interference to both cell interior and edge users.

There are two possible versions of SFR scheme:

  • In first version, the sub-band dedicated for the cell-edge UEs may also be used by the cell-center UEs but with reduced power level and only if it is not occupied by the cell-edge UEs. Cell-center sub-band is available to the centre UEs only. Figure Soft Frequency Reuse scheme version 1 below presents frequency and power plan for this version of Soft Frequency Reuse scheme.

    _images/fr-soft-frequency-reuse-scheme-v1.png

    Soft Frequency Reuse scheme version 1

  • In second version, cell-center UEs do not have access to cell-edge sub-band. In this way, each cell can use the whole system bandwidth while reducing the interference to the neighbors cells. From the other hand, lower ICI level at the cell-edge is achieved at the expense of lower spectrum utilization. Figure Soft Frequency Reuse scheme version 2 below presents frequency and power plan for this version of Soft Frequency Reuse scheme.

    _images/fr-soft-frequency-reuse-scheme-v2.png

    Soft Frequency Reuse scheme version 2

SFR algorithm maintain two maps. If UE should be served with lower power level, its RNTI is added to m_lowPowerSubBandUe map. If UE should be served with higher power level, its RNTI is added to m_highPowerSubBandUe map. To decide with which power level UE should be served SFR algorithm utilize UE measurements, and compares them to threshold. Signal quality threshold and PdschConfigDedicated (i.e. P_A value) for inner and outer area can be configured by attributes system. SFR utilizes Downlink Power Control described here.

Soft Fractional Frequency Reuse

Soft Fractional Frequency Reuse (SFFR) is an combination of Strict and Soft Frequency Reuse schemes. While Strict FR do not use the subbands allocated for outer region in the adjacent cells, soft FFR uses these subbands for the inner UEs with low transmit power. As a result, the SFFR, like SFR, use the subband with high transmit power level and with low transmit power level. Unlike the Soft FR and like Strict FR, the Soft FFR uses the common sub-band which can enhance the throughput of the inner users.

Figure Soft Fractional Fractional Frequency Reuse scheme below presents frequency and power plan for Soft Fractional Frequency Reuse.

_images/fr-soft-fractional-frequency-reuse-scheme.png

Soft Fractional Fractional Frequency Reuse scheme

Enhanced Fractional Frequency Reuse

Enhanced Fractional Frequency Reuse (EFFR) described in [ZXie2009] defines 3 cell-types for directly neighboring cells in a cellular system, and reserves for each cell-type a part of the whole frequency band named Primary Segment, which among different type cells should be orthogonal. The remaining subchannels constitute the Secondary Segment. The Primary Segment of a cell-type is at the same time a part of the Secondary Segments belonging to the other two cell-types. Each cell can occupy all subchannels of its Primary Segment at will, whereas only a part of subchannels in the Secondary Segment can be used by this cell in an interference-aware manner.The Primary Segment of each cell is divided into a reuse-3 part and reuse-1 part. The reuse-1 part can be reused by all types of cells in the system, whereas reuse-3 part can only be exclusively reused by other same type cells( i.e. the reuse-3 subchannels cannot be reused by directly neighboring cells). On the Secondary Segment cell acts as a guest, and occupying secondary subchannels is actually reuse the primary subchannels belonging to the directly neighboring cells, thus reuse on the Secondary Segment by each cell should conform to two rules:

  • monitor before use

  • resource reuse based on SINR estimation

Each cell listens on every secondary subchannel all the time. And before occupation, it makes SINR evaluation according to the gathered channel quality information (CQI) and chooses resources with best estimation values for reuse. If CQI value for RBG is above configured threshold for some user, transmission for this user can be performed using this RBG.

In [ZXie2009] scheduling process is described, it consist of three steps and two scheduling polices. Since none of currently implemented schedulers allow for this behaviour, some simplification were applied. In our implementation reuse-1 subchannels can be used only by cell center users. Reuse-3 subchannels can be used by edge users, and only if there is no edge user, transmission for cell center users can be served in reuse-3 subchannels.

Figure Enhanced Fractional Fractional Frequency Reuse scheme below presents frequency and power plan for Enhanced Fractional Frequency Reuse.

_images/fr-enhanced-fractional-frequency-reuse-scheme.png

Enhanced Fractional Fractional Frequency Reuse scheme

Distributed Fractional Frequency Reuse

This Distributed Fractional Frequency Reuse Algorithm was presented in [DKimura2012]. It automatically optimizes cell-edge sub-bands by focusing on user distribution (in particular, receive-power distribution). This algorithm adaptively selects RBs for cell-edge sub-band on basis of coordination information from adjecent cells and notifies the base stations of the adjacent cells, which RBs it selected to use in edge sub-band. The base station of each cell uses the received information and the following equation to compute cell-edge-band metric A_{k} for each RB.

A_{k} = \sum_{j\in J}w_{j}X_{j,k}

where J is a set of neighbor cells, X_{j,k}=\{0,1\} is the RNTP from the j-th neighbor cell. It takes a value of 1 when the k-th RB in the j-th neighbor cell is used as a cell-edge sub-band and 0 otherwise. The symbol w_{j} denotes weight with respect to adjacent cell j, that is, the number of users for which the difference between the power of the signal received from the serving cell i and the power of the signal received from the adjacent cell j is less than a threshold value (i.e., the number of users near the cell edge in the service cell). A large received power difference means that cell-edge users in the i-th cell suffer strong interference from the j-th cell.

The RB for which metric A_{k} is smallest is considered to be least affected by interference from another cell. Serving cell selects a configured number of RBs as cell-edge sub-band in ascending order of A_{k}. As a result, the RBs in which a small number of cell-edge users receive high interference from adjacent base stations are selected.

The updated RNTP is then sent to all the neighbor cells. In order to avoid the meaningless oscillation of cell-edge-band selection, a base station ignores an RNTP from another base station that has larger cell ID than the base station.

Repeating this process across all cells enables the allocation of RBs to cell-edge areas to be optimized over the system and to be adjusted with changes in user distribution.

Figure Sequence diagram of Distributed Frequency Reuse Scheme below presents sequence diagram of Distributed Fractional Frequency Reuse Scheme.

_images/ffr-distributed-scheme.png

Sequence diagram of Distributed Frequency Reuse Scheme

Carrier Aggregation

Overview

This section describes the ns-3 support for Carrier Aggregation. The references in the standard are [TS36211], [TS36213] and [TS36331].

Note: Carrier Aggregation was introduced in release 3.27 and currently, only works in downlink.

3GPP standardizes, in release R10, the Carrier Aggregation (CA) technology.

This technology consists of the possibility, to aggregate radio resources belonging to different carriers, in order to have more bandwidth available, and to achieve a higher throughput. Carrier Aggregation as defined by 3GPP can be used with both TDD and FDD. Since ns-3 only supports FDD LTE implementation, we will consider only this case in this section. Each aggregated carrier is referred to as a component carrier, CC. The component carrier can have a bandwidth of 1.4, 3, 5, 10, 15 or 20 MHz and a maximum of five component carriers can be aggregated, hence the maximum aggregated bandwidth is 100 MHz. In FDD the number of aggregated carriers can be different in DL and UL. However, the number of UL component carriers is always equal to or lower than the number of DL component carriers. The individual component carriers can also be of different bandwidths. When carrier aggregation is used there are a number of serving cells, one for each component carrier. The coverage of the serving cells may differ, for example due to that CCs on different frequency bands will experience different pathloss. The RRC connection is only handled by one cell, the Primary serving cell, served by the Primary component carrier (DL and UL PCC). It is also on the DL PCC that the UE receives NAS information, such as security parameters.

3GPP defines three different CA bandwidth classes in releases 10 and 11 (where ATBC is Aggregated Transmission Bandwidth Configuration):

Class A: ATBC \leq 100, maximum number of CC = 1

Class B: ATBC \leq 100, maximum number of CC = 2

Class C: 100 \leq ATBC \leq 200, maximum number of CC = 2

Figure CA impact on different layers of LTE protocol stack (from 3gpp.org) (from 3gpp.org) shows the main impact of CA technology on the different layers of the LTE protocol stack. Introduction of carrier aggregation influences mainly the MAC and new RRC messages are introduced. In order to keep R8/R9 compatibility the protocol changes will be kept to a minimum. Basically each component carrier is treated as an R8 carrier. However some changes are required, such as new RRC messages in order to handle the secondary component carrier (SCC), and MAC must be able to handle scheduling on a number of CCs. In the following we describe the impact of the carrier aggregation implementation on the different layers of the LTE protocol stack in ns-3.

_images/carrier-aggregation-impact.png

CA impact on different layers of LTE protocol stack (from 3gpp.org)

Impact on RRC layer

The main impacts on the RRC layer are related to secondary carrier configuration and measurements reporting. To enable these features we have enhanced the already existing procedures for the RRC Connection Reconfiguration and UE RRC Measurements Model.

The carrier aggregation enabling procedure is shown in figure A schematic overview of the secondary carrier enabling procedure. As per 3GPP definition, the secondary cell is a cell, operating on a secondary frequency, which may be configured once an RRC connection is established and which may be used to provide additional radio resources. Hence, the procedure starts when the UE is in the CONNECTED_NORMALLY state (see the RRC state machine description). This part of the procedure is the same as in the previous architecture. In order to simplify the implementation, the UE Capability Inquiry and UE Capability Information are not implemented. This implies to assume that each UE can support the carrier aggregation, and any specific configuration provided by the eNB to which is attached. The eNB RRC sends to the UE the secondary carrier configuration parameters through the RRC Connection Reconfiguration procedure. This procedure may be used for various purposes related to modifications of the RRC connection, e.g. to establish, modify or release RBs, to perform handover, to setup, modify or release measurements, to add, modify and release secondary cells (SCells). At UE side, the RRC is extended to configure the lower layers, in such a way that the SCell(s) are considered. Once the carriers are configured, the Reconfiguration Completed message is sent back to the eNB RRC, informing the eNB RRC and CCM that the secondary carriers have been properly configured. The RRC layer at both the UE and the eNB sides is extended to allow measurement reporting for the secondary carriers. Finally, in order to allow the procedures for configuration and measurement reporting, the RRC is enhanced to support serialization and deserialization of RRC message structures that carry information related to the secondary carriers, e.g., if the RRCConnectionReconfiguration message includes sCellToAddModList structure, SCell addition or modification will be performed, or, if it contains measConfig the measurement reporting will be configured. To allow transmission of this information the following structures are implemented for the sCell: RadioResourceConfigCommonSCell, RadioResourceConfigDedicatedSCell and PhysicalConfigDedicatedSCell and NonCriticalExtensionConfiguration. RadioResourceConfigCommonSCell and RadioResourceConfigDedicatedSCell are used for SCell addition and modification (see TS 36.331, 5.3.10.3b). PhysicalConfigDedicatedSCell is used for physical channel reconfiguration (see TS 36.331, 5.3.10.6). Finally, NonCriticalExtensionConfiguration is used to carry information of sCellToAddModeList and sCellToReleaseList, which is a modified structure comparing to TS 36.331, 6.6.2, according to which these are directly in the root of RRCConnectionReconfiguration message. Measurement reporting is extended with measResultSCell structure to include RSRP and RSRQ measurements for each configured SCell. However, the measurement report triggering event A6 (neighbour becomes offset better than SCell) is not implemented yet.

_images/ca-rrc-reconf.png

A schematic overview of the secondary carrier enabling procedure

Handover is possible between different component carriers on the same eNB (i.e., intra-eNB handover from one frequency to another) and between carriers on different eNB (i.e., inter-eNB). One constraint for inter-eNB handovers is that both eNB must have the same number of component carriers.

Impact on PDCP layer

There is no impact on PDCP layer.

Impact on RLC layer

The impact on the RLC layer is relatively small. There is some impact on configuration of the buffer and the usage of SAP interfaces between RLC and MAC. Since the capacity of the lower layers increases with the carrier aggregation it is necessary to accordingly adjust the size of the RLC buffer. The impact on the implementation of the RLC layer is very small thanks to the design choice that allows the CCM manager to serve the different RLC instances through the LteMacSapProvider interface. Thanks to this design choice, the RLC is using the same interface as in the earlier LTE module architecture, the LteMacSapProvider, but the actual SAP provider in the new architecture is the CCM (some class that inherits LteEnbComponentCarrierManager). The CCM acts as a proxy, it receives function calls that are meant for the MAC, and forwards them to the MAC of the different component carriers. Additionally, it uses the information of the UEs and the logical channels for its own functionalities.

Impact on MAC layer

The impact on the MAC layer depends on the CA scheduling scheme in use. Two different scheduling schemes are proposed in R10 and are shown in figure CA scheduling schemes (from 3gpp.org).

_images/carrier-aggregation-mac-impact.png

CA scheduling schemes (from 3gpp.org)

The CIF (Carrier Indicator Field) on PDCCH (represented by the red area) indicates on which carrier the scheduled resource is located. In the following we describe both the schemes:

  1. scheduling grant and resources on the same carrier. One PDCCH is supported per carrier.

  2. cross-carrier scheduling: it is used to schedule resources on the secondary carrier without PDCCH.

Current implementation covers only option 1, so there is no cross-carrier scheduling. The MAC layer of the eNodeB has suffered minor changes and they are mainly related to addition of component carrier information in message exchange between layers.

Impact on PHY layer

The impact on PHY layer is minor. There is an instance of PHY layer per each component carrier and the SAP interface functions remain unchanged. As shown in CA scheduling schemes (from 3gpp.org) the difference is that since there are multiple PHY instances, there are also multiple instances of PDCCH, HARQ, ACK/NACK and CSI per carrier. So, at the eNB PHY, the changes are related to the addition of the component carrier id information, while at the UE PHY the information of the Component Carrier is used for some functionalities that depend on the Component Carrier to which the PHY instance belongs. For example, the UE PHY is extended to allow disabling of the sounding reference signal (SRS) at the secondary carriers. This is necessary because there is one UE PHY instance per component carrier, but according to CA scheduling schemes (from 3gpp.org), only a single carrier is used and the uplink traffic is transmitted only over the primary carrier.

Code Structure Design

This section briefly introduces the software design and implementation of the carrier aggregation functionality.

Both LteEnbNetDevice and LteUeNetDevice are created by the LteHelper using the method InstallSingleEnbDevice and InstallSingleUeDevice. These functions are now extended to allow the carrier aggregation configuration. In the following we explain the main differences comparing to the previous architecture.

Figure Changes in LteEnbNetDevice to support CA shows the attributes and associations of the LteEnbNetDevice that are affected by the implementation, or are created in order to support the carrier aggregation functionality. Since LteEnbNetDevice may have several component carriers, the attributes that were formerly part of the LteEnbNetDevice and are carrier specific are migrated to the ComponentCarrier class, e.g. physical layer configuration parameters. The attributes that are specific for the eNB component carrier are migrated to ComponentCarrierEnb, e.g. pointers to MAC, PHY, scheduler, fractional frequency reuse instances. LteEnbNetDevice can contain pointers to several ComponentCarrierEnb instances. This architecture allows that each CC may have its own configuration for PHY, MAC, scheduling algorithm and franctional frequency reuse algorithm. These attributes are currently maintained also in the LteEnbNetDevice for backward compatibility purpose. By default the LteEnbNetDevice attributes are the same as the primary carrier attributes.

_images/ca-lte-enb-net-device-changes.png

Changes in LteEnbNetDevice to support CA

Figure Changes in LteUeNetDevice to support CA shows the attributes and associations of LteUeNetDevice that are affected by the carrier aggregation implementation. Similarly, to the changes in LteEnbNetDevice, pointers that are specific to UE component carrier are migrated to the ComponentCarrierUe class. LteUeNetDevice has maintained m_dlEarfcn for initial cell selection purposes.

_images/ca-lte-ue-net-device-changes.png

Changes in LteUeNetDevice to support CA

CA impact on data plane of eNodeB

Figure eNB Data Plane Architecture shows the class diagram of the data plane at the eNB.

The main impact is the insertion of the LteEnbComponentCarrierManager class in the middle of the LTE protocol stack. During the design phase it was decided to keep the same SAP interfaces design that existed between MAC and RLC in order to avoid unnecessary changes in these parts of protocol stack. To achieve this the LteEnbComponentCarrierManager implements all functions that were previously exposed by RLC to MAC through LteMacSapUser interface. It also implements functions that were previously exposed by MAC to RLC through the LteMacSapProvider interface. In this way, the carrier aggregation is transparent to upper and lower layers. The only difference is that the MAC instance sees now only one LteMacSapUser, whereas formerly it was seeing only one LteMacSapUser per RLC instance.

The LteEnbComponentCarrierManager is responsible for the forwarding messages in both directions. In the current implementation, a PDCP and a RLC instances are activated each time a new data radio bearer is configured. The correspondence between a new data radio bearer and a RLC instance is one to one. In order to maintain the same behavior, when a new logical channel is activated, the logical channel configurations is propagated to each MAC layer object in “as is” fashion.

_images/ca-enb-data-plane.png

eNB Data Plane Architecture

Figure Sequence Diagram of downlink buffer status reporting (BSR) with CA shows a sequence diagram of downlink buffer status reporting with a carrier aggregation implementation of only one secondary carrier. Each time that an RLC instance sends a buffer status report (BSR), the LteEnbComponentCarrierManager propagates the BSR to the MAC instances. The LteEnbComponentCarrierManager may modify a BSR before sending it to the MAC instances. This modification depends on the traffic split algorithm implemented in CCM class that inherits LteEnbComponentCarrierManager.

_images/ca-downlink-bsr.png

Sequence Diagram of downlink buffer status reporting (BSR) with CA

CA impact on control plane of eNodeB

Figure eNB Control Plane Architecture shows the class diagram of the control plane at the eNB. During the design phase it was decided to maintain the same hooks as in the former architecture. To do so, at each component carrier the PHY and the MAC are directly associated to the RRC instance. However, the RRC instance is additionally connected to the LteEnbComponentCarrierManager, which is responsible for enabling and disabling the component carriers. When the simulation starts, the number of component carrier is fixed, but only the primary carrier component is enabled. Depending on the LteEnbComponentCarrierManager algorithm the other carrier components could be activated or not.

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eNB Control Plane Architecture

Figure Sequence Diagram of Data Radio Bearer Setup shows how the Radio Bearer are configured.

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Sequence Diagram of Data Radio Bearer Setup

CA impact on data plane of UE

Figure UE Data Plane Architecture shows the relation between the different classes related to the UE data plane. The UE data plane architecture is similar to the eNB data plane implementation. The LteUeComponentCarrierManager is responsible to (re)map each MacSapUserProvider to the corresponding RLC instance or to the proper MAC instance. The channel remapping depends on algorithm used as LteUeComponentCarrierManager. A particular case is represented by the UE buffer status report (BSR) to eNB. Since, i) the standard does not specify how the BSR has to be reported on each component carrier and ii) it is decided to map one-to-one the logical channel to each MAC layer, the only way to send BSRs to the eNB is through the primary carrier. Figure Uplink buffer status reporting with CA shows the sequence diagram. Each time a BSR is generated, the LteUeComponentCarrierManager sends it through the primary carrier component. When the primary component carrier at the eNB receives the BSR, it sends it to LteEnbComponentCarrierManager. The latter, according to algorithm dependent policies, forwards a BSR to component carriers. The communication between the LteEnbMac and the LteEnbComponentCarrierManager is done through a specific set of SAP functions which are implemented in the LteUlCcmRrcSapUser and the LteUlCcmRrcSapProvider.

_images/ca-ue-data-plane.png

UE Data Plane Architecture

_images/ca-uplink-bsr.png

Uplink buffer status reporting with CA

CA impact on control plane of UE

Figure UE Control Plane Architecture shows the relation between the different classes associated to the UE control plane. The control plane implementation at the UE is basically the same as the eNB control plane implementation. Each component carrier control SAP (both for PHY and MAC layer objects) is linked in a one-to-one fashion directly to the RRC instance. The Ue RRC instance is then connected to the LteUeComponentCarrierManager in the same way as in the eNB.

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UE Control Plane Architecture

CCHelper is the class that is implemented to help the configuration of the physical layer parameters, such as uplink and downlink,bandwidth and EARFCN of each carrier.

CCM RRC MAC interfaces

The Component carrier manager (CCM) is also developed by using the SAP interface design. The following SAP interfaces are implemented for CCM and MAC:

  • the LteCcmMacSapUser part is provided by MAC and is used by the CCM

  • the LteCcmMacSapProvider part is provided by CCM and is used by the MAC layer

When the primary component carrier receives an uplink BSR it uses the LteCcmMacSapUser to forward it to the CCM, which should decide how to split the traffic corresponding to this BSR among carriers. Once this decision is made, the CCM uses the LteCcmMacSapProvider interface to send back an uplink BSR to some of the MAC instances. Additionally, the LteCcmMacSapUser can be used by the MAC to notify about the PRB occupancy in the downlink to the CCM. This information may be used by the CCM to decide how to split the traffic and whether to use the secondary carriers.

CCM RRC SAP interfaces

The following SAP interfaces are implemented for CCM and RRC:

  • the LteCcmRrcSapProvider is provided by the CCM and is used by the RRC layer

  • the LteCcmRrcSapUser is provided by RRC and is used by the CCM

By using the LteCcmRrcSapUser the CCM may request a specific measurement reporting configuration to be fulfilled by the UEs attached to the eNB. When a UE measurement report is received, as a result of this configuration, the eNB RRC entity shall forward this report to the CCM through the LteCcmRrcSapProvider::ReportUeMeas SAP function. Additionally, the LteCcmRrcSapProvider offers different functions to the RRC that can be used to add and remove of UEs, setup or release of radio bearer, configuration of the signalling bearer, etc.

Component carrier managers

Currently, there are two component carrier manager implementations available. The first one is the NoOpComponentCarrierManager, which is the default CCM choice. When this CCM is used the carrier aggregation feature is disabled. This CCM forwards all traffic, the uplink and the downlink, over the primary carrier, and does not use secondary carriers. Another implementation is the RrComponentCarrierManager, which splits the traffic equally among carriers, by diving the buffer status report among different carriers. SRB0 and SRB1 flows will be forwarded only over primary carrier.

Helpers

Two helper objects are used to setup simulations and configure the various components. These objects are:

  • LteHelper, which takes care of the configuration of the LTE radio access network, as well as of coordinating the setup and release of EPS bearers. The LteHelper class provides both the API definition and its implementation.

  • EpcHelper, which takes care of the configuration of the Evolved Packet Core. The EpcHelper class is an abstract base class, which only provides the API definition; the implementation is delegated to the child classes in order to allow for different EPC network models.

A third helper object is used to configure the Carrier Aggregation functionality:

  • CcHelper, which takes care of the configuration of the LteEnbComponentCarrierMap, basically, it creates a user specified number of LteEnbComponentCarrier. LteUeComponentCarrierMap is currently created starting from the LteEnbComponentCarrierMap. LteHelper:InstallSingleUeDevice, in this implementation, is needed to invoke after the LteHelper:InstallSingleEnbDevice to ensure that the LteEnbComponentCarrierMap is properly initialized.

It is possible to create a simple LTE-only simulations by using the LteHelper alone, or to create complete LTE-EPC simulations by using both LteHelper and EpcHelper. When both helpers are used, they interact in a master-slave fashion, with the LteHelper being the Master that interacts directly with the user program, and the EpcHelper working “under the hood” to configure the EPC upon explicit methods called by the LteHelper. The exact interactions are displayed in the Figure Sequence diagram of the interaction between LteHelper and EpcHelper..

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Sequence diagram of the interaction between LteHelper and EpcHelper.