Mobility Management Overview
-Mobility
management is classified into mobility management in idle mode and mobility
management in connected mode, based on RRC states. A UE with an RRC connection
to the radio network is considered to be in connected mode. In the case of
mobility management in connected mode, an eNodeB
delivers the associated configuration through signaling on the control plane,
and UEs perform measurements accordingly and complete the handover procedures
under the control of the eNodeB,
thus ensuring uninterrupted service provision.
-In
the case of mobility management in connected mode, the mobile network ensures
continuity of physical channels and provides uninterrupted communications
service for UEs in connected mode through handovers when the UEs are moving in
the network. A handover is a procedure where the serving cell of a UE in
connected mode is changed. Handovers can be classified into intra-frequency
handover, inter-frequency handover, and inter-RAT handover.
Classification of Handover
+Intra-frequency
Handover
-Intra-frequency handover is performed
between cells on the same frequency in the LTE system.
+Inter-frequency
Handover
-Inter-frequency
handover is performed between cells on different frequencies in the LTE system.
+Inter-RAT
Handover
-Inter-RAT handover is performed from LTE
to GSM/WCDMA/TD-SCDMA/CDMA2000
+All the handover involve 3 setups
Measurement
step: UE strart
intra-frequency or inter-frequency measurement according to the different
triggers
Decision
step: eNodeB
make handover decision according to the resource state and related parameters
Execution
step: eNodeB
send execution command to UE to perform handover
Different types of handover measurement are triggered by different causes
Handover Type:
1- Coverage based:
Intra-frequency :The
measurement configuration is performed when the UE establishes a radio bearer.
The UE performs intra-frequency measurements by default.
Inter-frequency/ Inter-RAT :The eNodeB
delivers the measurement configuration to the UE when the signal quality in the
serving cell is lower than the associated threshold.
2-Load
based(Intra-frequency / Inter-frequency / Inter-RAT) :The
measurements are triggered by the Mobility Load Balancing (MLB) algorithm.
3-Frequency-priority-based (Inter-frequency) : The measurements are triggered by A1 event
4- Service
based (Inter-RAT/Inter-frequency) : The eNodeB
triggers the measurements after it finds that only the voice service is running
on the UE.
5-UL
service
quality Based(Inter-RAT/Inter-frequency) : The eNodeB
triggers the measurement
after it detects UL power insufficient at the UE
6-Distance based(Inter
– frequency/Inter -RAT):The
measurements are triggered by distance if it is more than the
specific threshold
Measurement Control Configuration :
+eNodeB should deliver all the measurement control parameters to UE via RRC reconfiguration, including measurement object, report configuration, measurement ID and filter configuration .
+Besides, for inter-frequency/inter-RAT measurement, it also includes gap configuration for gap-assisted measurement.
When a UE establishes a radio bearer, the eNodeB delivers the intra-frequency measurement configuration to the UE through an RRC Connection Reconfiguration message by default. Then, the UE performs intra-frequency measurements by default.
When measurement gaps need to be set up, the eNodeB delivers the inter-frequency and/or inter-RAT measurement configuration to the UE. After that, the UE performs gap-assisted inter-frequency and/or inter-RAT measurements. Inter-frequency and inter-RAT measurements can use the same gap pattern, but the eNodeB is able to differentiate between the gap configurations for inter-frequency and inter-RAT measurements.
Events :
EVENT A1
* Event A1 is triggered when the serving cell becomes better than a threshold. The event is triggered when the following condition is
true:
Meas serv - Hyst > Threshold
* Triggering of the event is subsequently cancelled when the following condition is true:
Me as serv + Hyst < Threshold
* The hysteresis can be configured with a value between 0 and 30 dB
* When using RSRP, the threshold can be configured with a value between -140 and -44 dBm. The value of the threshold is signalled
using the mapping presented in Table 242 (using a signalled value of between 0 and 97)
* When using RSRQ, the threshold can be configured with a value between -3 and -19.5 dB. The value of the threshold is signalled
using the mapping presented in Table 243 (using a signalled value of between 0 and 34)
EVENT A2
* Event A2 is triggered when the serving cell becomes worse than a threshold. The event is triggered when the following condition is
true:
Meas serv + Hyst < Threshold
* Triggering of the event is subsequently cancelled when the following condition is true:
Me as serv - Hyst > Threshold
* The hysteresis can be configured with a value between 0 and 30 dB
* When using RSRP, the threshold can be configured with a value between -140 and -44 dBm. The value of the threshold is signalled
using the mapping presented in Table 242 (using a signalled value of between 0 and 97)
* When using RSRQ, the threshold can be configured with a value between -3 and -19.5 dB. The value of the threshold is signalled
using the mapping presented in Table 243 (using a signalled value of between 0 and 34)
EVENT A3
* Event A3 is triggered when a neighbouring cell becomes better than the serving cell by an offset. The offset can be either positive or
negative. The event is triggered when the following condition is true:
Meas neigh + 0 neigh,Jreq + 0 neigh,cell - Hyst > Me as serv + 0 serv,Jreq + 0 serv,cell +Offset
* Triggering of the event is subsequently cancelled when the following condition is true:
Meas neigh + 0 neigh,freq + 0 neigh,cell + Hyst < Meas serv + 0 serv,freq + 0 serv,cell +Offset
* Both the neighbour and serving cell can have frequency specific and cell specific offsets applied to their measurements. Each of these
offsets can be configured with values between -24 and +24 dB
* The additional Offset added to the serving cell measurement can be configured with a value between -30 and +30 dB
* The hysteresis can be configured with a value between 0 and 30 dB
EVENT A4
* Event A4 is triggered when a neighbouring cell becomes better than a threshold. The event is triggered when the following condition
is true:
Meas neigh + 0 neigh,freq + 0 neigh,ce/1 - Hyst > Threshold
* Triggering of the event is subsequently cancelled when the following condition is true:
Me as neigh + 0 neigh,freq + 0 neigh ,ce/1 + Hyst < Threshold
* The neighbour cell can have frequency specific and cell specific offsets applied to its measurements. Both offsets can be configured
with values between -24 and +24 dB
* The hysteresis can be configured with a value between 0 and 30 dB
* When using RSRP, the threshold can be configured with a value between -140 and -44 dBm. The value of the threshold is signalled
using the mapping presented in Table 242 (using a signalled value of between 0 and 97)
* When using RSRQ, the threshold can be configured with a value between -3 and -19.S dB. The value of the threshold is signalled
using the mapping presented in Table 243 (using a signalled value of between 0 and 34)
* UE support for event A4 is intended to be mandatory, but event A4 may not have been implemented and tested for some early devices.
UE use release 8 Feature Group Indicator (FGI) bit 14 to indicate whether or not event A4 has been implemented and tested. The FGI
bit string can be included within a UE Capability Information message
EVENT A5
* Event A5 is triggered when the serving cell becomes worse than threshold! while a neighboring cell becomes better than threshold2.
The event is triggered when both of the following conditions are true:
Me as serv + Hyst < Threshold!
Meas neigh + 0 neigh,freq + 0 neigh,cell - Hyst > Threshold2
* Triggering of the event is subsequently cancelled when either of the following conditions are true:
Me as serv - Hyst > Threshold!
Meas neigh + 0 neigh,freq + 0 neigh,cell + Hyst < Threshold2
* The neighbour cell can have frequency specific and cell specific offsets applied to its measurements. Both offsets can be configured
with a value between -24 and +24 dB
* The hysteresis can be configured with a value between 0 and 30 dB
* When using RSRP, the threshold can be configured with a value between -140 and -44 dBm. The value of the threshold is signalled
using the mapping presented in Table 242 (using a signalled value of between 0 and 97)
* When using RSRQ, the threshold can be configured with a value between -3 and -19.S dB. The value ofthe threshold is signalled
using the mapping presented in Table 243 (using a signalled value of between 0 and 34)
* UE support for event AS is intended to be mandatory, but event AS may not have been implemented and tested for some early devices.
UE use release 8 Feature Group Indicator (FGI) bit 14 to indicate whether or not event AS has been implemented and tested. The FGI
bit string can be included within a UE Capability Information message
EVENT A6
* Event A6 is triggered when a neighbouring cell becomes better than a secondary cell by an offset. The offset can be either positive or
negative.
* This measurement reporting event is applicable to L TE Advanced connections using Carrier Aggregation, i.e. connections which have
secondary serving cells (in addition to a primary serving cell)
* The event is triggered when the following condition is true:
Measneigh + Oneigh,cell - Hyst > Me as sec + Osec,cell +Offset
* Triggering of the event is subsequently cancelled when the following condition is true:
Measneigh + Oneigh,cell + Hyst < Meassec + Osec,cell +Offset
* The neighbour cell has to be on the same frequency as the secondary serving cell
* Both the neighbour and secondary serving cell can have cell specific offsets applied to their measurements. Each of these offsets can
be configured with values between -24 and +24 dB
* The additional Offset added to the secondary serving cell measurement can be configured with a value between -30 and +30 dB
* The hysteresis can be configured with a value between 0 and 30 dB
* UE support for event A6 is intended to be mandatory for all 3GPP release I 0 UE which support Carrier Aggregation. Nevertheless,
event A6 may not have been implemented and tested for some early release I 0 devices. UE use release I 0 Feature Group Indicator
(FGI) bit II to indicate whether or not event A6 has been implemented and tested. UE are only permitted to signal their support for
event A6 if they support Carrier Aggregation. The FGI bit string can be included within a UE Capability Information message
EVENT B1
* Event B 1 is triggered when a neighbouring inter-system cell becomes better than a threshold. The event is triggered when the
following condition is true:
Me as neigh + 0 neigh,Jreq - Hyst > Threshold
* Triggering of the event is subsequently cancelled when the following condition is true:
Meas neigh + 0 neighJreq + Hyst < Threshold
* The inter-system neighbour cell can have a frequency specific offset applied to its measurements. Cell specific offsets are not
applicable to inter-system measurements. The offset can be configured with a value between -15 and + 15 dB
* The hysteresis can be configured with a value between 0 and 30 dB
* When using CPICH RSCP, the threshold can be configured with a value between -120 and -25 dBm. The value of the threshold is
signalled using the mapping specified in 3GPP TS 25.133 (using a signalled value of between -5 and 91)
* When using CPICH Ec/Io, the threshold can be configured with a value between -24 and 0 dB. The value of the threshold is signalled
using the mapping specified in 3GPP TS 25.133 (using a signalled value of between 0 and 49)
* When using GSM RSSI, the threshold can be configured with a value between -110 and -48 dB. The value of the threshold is signalled
using the mapping specified in 3GPP TS 45.008 (using a signalled value of between 0 and 63)
* UE support for event Bl is intended to be mandatory for UE which support inter-RAT measurements. Nevertheless, event Bl may not
have been implemented and tested for some early devices. UE use release 8 Feature Group Indicator (FGI) bit 15 to indicate whether
or not event B 1 has been implemented and tested. UE are only permitted to signal their support for event B 1 if they support inter-RAT
measurements for UTRAN, GERAN, CDMA2000 lxRTT or CDMA2000 HRPD (FGI bits 22, 23, 24 and 26 respectively). The FGI
bit string can be included within a UE Capability Information message
EVENT B2
* Event B2 is triggered when the serving cell becomes worse than threshold! while a neighbouring inter-system cell becomes better than
threshold2. The event is triggered when both of the following conditions are true:
Meas serv + Hyst < Threshold!
Meas neigh + 0 neigh,Jreq - Hyst > Threshold2
* Triggering of the event is subsequently cancelled when either of the following conditions are true:
Me as serv - Hyst > Threshold!
Me as neigh + 0 neigh,Jreq + Hyst < Threshold2
* The inter-system neighbour cell can have a frequency specific offset applied to its measurements. Cell specific offsets are not
applicable to inter-system measurements. The offset can be configured with a value between -15 and+ 15 dB
* The hysteresis can be configured with a value between 0 and 30 dB
* When using CPICH RSCP, threshold2 can be configured with a value between -120 and -25 dBm. The value of the threshold is
signalled using the mapping specified in 3GPP TS 25.133 (using a signalled value of between -5 and 91)
* When using CPICH Ec/Io, threshold2 can be configured with a value between -24 and 0 dB. The value of the threshold is signalled
using the mapping specified in 3GPP TS 25.133 (using a signalled value of between 0 and 49)
* When using GSM RSSI, threshold2 can be configured with a value between -110 and -48 dB. The value of the threshold is signalled
using the mapping specified in 3GPP TS 45.008 (using a signalled value of between 0 and 63)
* UE support for event B2 is intended to be mandatory for UE which support inter-RAT measurements. Nevertheless, event B2 may not
have been implemented and tested for some early devices. UE use release 8 Feature Group Indicator (FGI) bits 22, 23, 24 and 26 to
indicate whether or not event B2 has been implemented and tested for UTRAN, GERAN, CDMA2000 lxRTT and CDMA2000
HRPD respectively. These FGI bits also indicate UE support for the relevant inter-RAT measurements. The FGI bit string can be
included within a UE Capability Information message