LTE_KPI_V1

LTE RF/RAN Key Performance Indicators

S.NoKPI Name

1

E-RAB Setup Success Ratio

2

Initial E-RAB Setup Success Ratio

3

Additional E-RAB Setup Success Ratio

4 E-RAB Setup Attempts

5E-RAB Setup Failure Ratio due to Radio Network Layer Failure

6E-RAB Setup Failure Ratio due to Transport Layer Failure

7E-RAB Setup Failure Ratio due to Resource Failure

8E-RAB Setup Failure Ratio due Other Failure

9

S1 Initial Context Setup Success Ratio

10 S1 Initial Context Setup Attempts

11

12

13

S1 Initial Context Setup Failure Ratio due to Resource Failure

14

S1 Initial Context Setup Failure Ratio due Other Failure

15

S1 Setup Success Ratio

16 S1 Setup Attempts

17S1 Setup Failure Ratio due to No Response Failure

18S1 Setup Failure Ratio due to MME Failure

S1 Initial Context Setup Failure Ratio due to Radio Network Layer Failure

S1 Initial Context Setup Failure Ratio due to Transport Layer Failure

19

UE Context Modification Failure Rate

20 Data Radio Bearer Attempts

21

Data Radio Bearer Setup Success Ratio

22

Radio Bearer Drop Ratio

23

Radio Bearer Success Ratio

24

RRC Connection Setup Attempts due to MO Signaling

25

RRC Connection Setup Attempts due to MT- Access

26

RRC Connection Setup Attempts due to MO-Data

27

RRC Connection Setup Attempts due to others

28

RRC Connection Setup Attempts due to emergency calls

29

RRC Connection Setup Success Ratio

30

E-UTRAN RRC Connection Setup Success Ratio for emergency Calls

31

RRC Connection Failure Ratio due to RRC timer expiry

32

RRC Connection Failure Ratio due to RRC protocol error

33

RRC Connection Failure Ratio due to radio access control failure

34

35RRC Paging Discard Ratio

36 RRC Paging Records

37

E-RAB Drop Ratio, RAN View

38

39

RRC Connection Failure Ratio due to lack of RBs for emergency calls

E-RAB drop ratio due to radio network layer(RNL) cause initiated by eNB

E-RAB drop ratio due to transport network layer(TNL) cause initiated by eNB

40

41

42

43

E-RAB Normal Release Ratio, User Perspective

E-RAB drop ratio due to other (OTH) cause initiatedbe eNB

E-RAB drop ratio due to radio network layer(RNL) cause initiated by EPC

E-RAB drop ratio due to other (OTH) cause initiatedbe EPC

44

E-RAB Normal Release Ratio, RAN View

45E-RAB Setup Failure Ratio due to radio network layer failure (RNL)

46E-RAB Setup Failure Ratio due to transport layer failure (TRPORT)

47E-RAB Setup Failure Ratio due to resource failure (RESOUR)

48E-RAB Setup Failure Ratio due to other failure (OTH)

49

E-RAB Drop Ratio, User Perspective

50

51

52

53S1 Initial Context Setup Failure Ratio due to other failure (OTH)

54S1 Setup Failure Ratio due to "no response" failure

55S1 Setup Failure Ratio due to "MME" failure

56IP incoming Traffic Error Ratio

57

Average Latency Downlink

58

Average Latency Downlink for QCI1 DRBs

S1 Initial Context Setup Failure Ratio due to radio network layer failure (RNL)

S1 Initial Context Setup Failure Ratio due to radio transport layer failure (TRPORT)

S1 Initial Context Setup Failure Ratio due to resource failure (RESOUR)

59

Average Latency Downlink for non-GBR DRBs

60

Average Latency Uplink

61

RLC PDU Re-transmission Ratio Downlink

62

RLC PDU Re-transmission Ratio Uplink

63

Average RSSI for PUCCH

64

Average RSSI for PUSCH

65

Average SINR for PUCCH

66

Average SINR for PUSCH

67

Average CQI

68Average CQI Offset

69

HO Preparation Success Ratio, intra eNB

70HO Preparations, intra eNB

71

72

HO Preparation Failure Ratio due to other failure, intra eNB

73

HO Success Ratio, intra eNB

74 HO Attempts, intra eNB

75

HO Failure Ratio, intra eNB

76

Total HO Success Ratio, intra eNB

77

HO Preparation Success Ratio, inter eNB X2 based

78HO Preparation, inter eNB X2 based

79

HO Preparation Success Ratio, inter eNB S1 based

80HO Preparation, inter eNB S1 based

81

82

83

HO Preparation Failure Ratio due to admission control failure, intra eNB

HO Preparation Failure Ratio due to timer failure, inter eNB X2 based

HO Preparation Failure Ratio due to admission control failure,inter eNB X2 based

HO Preparation Failure Ratio due to other failure, inter eNB X2 based

84

85

86

87

HO Success Ratio, inter eNB X2 based

88HO Attempts, inter eNB X2 based

89

HO Success Ratio, inter eNB S1 based

90HO Attempts, inter eNB S1 based

91

HO Failure Ratio, inter eNB X2 based

92

HO Failure Ratio, inter eNB S1 based

93

Total HO Success Ratio, inter eNB X2 based

94

Total HO Success Ratio, inter eNB S1 based

HO Preparation Failure Ratio due to "timer TS1RELOCprep" failure, Inter eNB S1 based

HO Preparation Failure Ratio due to percentage of "lack of resources" failure , Inter eNB S1 based

HO Preparation Failure Ratio due to percentage of "other" failure , Inter eNB S1 based

95

96

97

98

Inter-Frequency HO Success Ratio

99

Inter-Frequency HO Success Ratio - Measurement Gap assisted

100Average PDCP Layer Cell Throughput Downlink

101Average PDCP Layer Cell Throughput Downlink for QCI1 DRBs

102Average PDCP Layer Cell Throughput Uplink

103Average PDCP Layer Cell Throughput Uplink for QCI1 DRBs

104Average RLC Layer Cell Throughput Downlink

105Average RLC Layer Cell Throughput Uplink

106Average incoming Signaling Throughput on X2

107

Average outgoing Signaling Throughput on X2

108Average incoming Data Throughput on X2

109Average outgoing Data Throughput on X2

110

Average PRB usage per TTI Downlink

111

Average PRB Usage per TTI Uplink

112

Cell Availability Ratio

113

Planned Cell Unavailability Ratio

CS Fallback Attempts with Redirection via RRC Connection Release Distribution Rate for UE in Connected mode

CS Fallback Attempts with Redirection via RRC Connection Release Distribution Rate for UE in Idle mode

CS Fallback Attempts with Redirection via RRC Connection Release Distribution Rate for Emergency call reason

114

Unplanned Cell Unavailability Ratio

115

Cell Availability, excluding blocked by user state (BLU)

116

Average Active UEs with data in the buffer per cell DL

117

118

119

Average Active UEs with data in the buffer per cell UL

120

121

122

Maximum Active UEs with data in the buffer per cell DL

123

Maximum Active UEs with data in the buffer per cell UL

124Average Active UEs per eNB

125IP incoming Traffic Volume

126IP outgoing Traffic Volume

127

IP incoming Traffic Throughput

128

IP outgoing Traffic Throughput

129IP incoming Traffic Error Ratio

130

Service Accessibility Ratio[%]

131Completed Session Ratio[%]

132

Service Access Time [s]

133Session Time [s]

Average Active UEs with data in the buffer for QCI1 DRBs per cell DL

Average Active UEs with data in the buffer for non-GBR DRBs per cell DL

Average Active UEs with data in the buffer for QCI1 DRBs per cell UL

Average Active UEs with data in the buffer for non-GBR DRBs per cell UL

134

Single User Data Rate [Mbps]

135

VoIP Call Setup Time [s]

136

VoIP Call Success Rate [%]

137

VoIP Call Drop Rate [%]

138

Speech Quality [MOS-CQ]

139

One-way Voice Delay (m2e) [ms]

140

Voice Frame Error Rate (FER) [%]

141Voice Interrupt Time (HO)

142

VoIP Capacity per Cell [n]

143

Attach Time [ms]

144

Detach Time [ms]

145

Attach Success Rate [%]

146

Service Request (EPS) Time [ms] UE Initiated

147

Service Request (EPS) Time [ms] Network Initiated

148

Service Request (EPS) Success Rate[%]

149

Service (EPS) Drop Rate [%]

150

Handover Procedure Time [ms]

151

Handover Success Rate [%]

152

Paging Time [ms]

153

Paging Failure Rate [%]

154

(LTE) Round Trip Time (RTT) [ms]

155

(LTE) Single User Data Rate [Mbps]

156

(LTE) Packet Loss Rate (PLR) [%]

157

(LTE) Service Interrupt Time (HO) [ms]

158

(RB) Packet Loss Rate UL / DL [%]

159

(RB) Single User Data Rate [Mbps]

160

Cell Throughput [Mbps]

161

(RB)Residual Block Error Rate(Residual BLER)

162 One Round Paging Sucess

163One round Tracking Area Update success

164SAE Bearer Setup Success Rate

165 Call Drop Rate

166 Intra LTE Handover Success Rate

KPI Description KPI Category

Accessibility

Accessibility

Accessibility

The KPI describes the number of E-RAB Setup Attempts. AccessibilityRetainability

Retainability

Retainability

Retainability

Accessibility

The KPI shows the number of S1 Initial Context Setup Attempts AccessibilityRetainability

Retainability

Retainability

Retainability

Accessibility

The KPI shows the number of S1 Setup Attempts. AccessibilityRetainability

Retainability

The KPI describes the setup success ratio of the elementary E-RAB setup procedure used to setup the E-RAB between MME and UE.It indicates the E-UTRAN contribution to network accessibilityfor the end-user, not the whole end-to-end service accessibility.

The KPI describes the setup success ratio of the elementary initial E-RAB setup procedure.It indicates the E-UTRAN contribution to network accessibility for the end-user, not the whole end-to-end service accessibility.

The KPI describes the setup success ratio of the elementary additional E-RAB setup procedure.It indicates the E-UTRAN contribution to network accessibility for the end-user, not the whole end-to-end service accessibility.

This KPI describes the ratio of a specific failure cause related to all EPS Bearer set up attempts




The KPI shows the setup success ratio for the elementaryprocedure "Initial Context Setup", used to set up the initial UEcontext in MME (UE-associated logical S1-connection).

This KPI describes the ratio of a specific failure cause relatedto all initial context setup attempts.




The KPI shows the setup success ratio for the elementaryprocedure "S1 Setup". When this procedure is finished, S1interface is operational and other S1 messages can be exchanged

This KPI describes the ratio of a specific S1 setup failurecause related to all S1 setup attempts.

This KPI describes the ratio of a specific S1 setup failurecause related to all S1 setup attempts.

Accessibility

The KPI shows the Data Radio Bearer Attempts. AccessibilityAccessibility

The KPI shows the ratio of dropped Radio Bearers Retainability

Retainability

Accessibility

Accessibility

Accessibility

Accessibility

Accessibility

Accessibility

Accessibility

The KPI is used to indicate some problems with UE ContextModification procedure (e.g. due to security reason, ENBdoes not support either requested modification or CSFallback feature).

The KPI shows the setup success ratio for the data radio bearersetup procedure. The elementary procedure "RRC connectionreconfiguration" is used in this context to setup a user plane(data) radio bearer.

The KPI shows the Radio Bearer Success Ratio given as 100- Radio Bearer Drop Ratio

The KPI shows the RRC Connection Setup Attempts on a percause basis.The RRC connection requests for emergencycalls may be also counted by some of the remaining KPIswithin this chapter. However for emergency calls it is mandatoryto provide also a separate KPI to monitortheir penetration into the network





The KPI shows the setup success ratio for the elementaryprocedure "RRC connection establishment" used to set up aradio connection from UE to eNB (involves SRB1 establishment).

The KPI shows the setup success ratio for the elementaryprocedure "RRC connection establishment" used to set up aradio connection from UE to eNB for emergency calls.

C32

Due to importance of emergency calls it is mandatory to provide an own KPI (in addition to LTE_5218a) to monitor their connection setup and penetration into the network.

Retainability

Retainability

Retainability

Retainability

This KPI describes the paging request discard ratio on RRC level Accessibility

This KPI shows the numbe rof RRC Paging Paging Records AccessibilityRetainability

Retainability

Retainability

This KPI describes the ratio of a specific RRC connectionsetup failure cause related to all RRC connection requests




This KPI describes the ratio of abnormally released (dropped)E-RABs from RAN point of view



C39

Each bearer of the "Bearer to be Released List" IE is counted. RAN point of view means that as abnormal E-RAB drops only those ones initiated by eNB are counted

C40


C41


Retainability

Retainability

Retainability

Retainability




This KPI describes the ratio of normally released E-RABsfrom user perspective. This KPI is corresponding to a ConnectionCompletion Ratio

C42


C43


C44


C45

Each bearer of the "Bearer to be Released List" IE is counted

Retainability

Retainability

Retainability

Retainability

Retainability

Retainability

Retainability

Retainability

This KPI shows the error ratio for IP based incoming traffic Retainability

Integrity/Quality

Integrity/Quality

This KPI describes the ratio of normally released E-RABsfrom RAN point of view.

This KPI describes the ratio of a specific failure cause relatedto all EPS Bearer set up attempts




This KPI describes the ratio of abnormally released (dropped)E-RABs from user perspective point of view

This KPI describes the ratio of a specific failure cause relatedto all initial context setup attempts




This KPI describes the ratio of a specific S1 setup failurecause related to all S1 setup attempts

This KPI describes the ratio of a specific S1 setup failurecause related to all S1 setup attempts

This KPI shows the retention period (delay) of a PDCP SDU(DL) inside eNB. Time from reception of an IP packet to thetransmission of the first packet over the Uu interface

This KPI shows the retention period (delay) of a PDCP SDU(DL) inside eNB for QCI1 DRBs. Time from reception of IPpacket to transmission of first packet over the Uu interface

C46

Each bearer of the "Bearer to be Released List" IE is counted

C51

Each bearer of the "Bearer to be Released List" IE is counted.User perspective point of view means that as abnormal ERAB drops both those ones initiated by eNB and EPC are counted

Integrity/Quality

Integrity/Quality

Integrity/Quality

Integrity/Quality

Integrity/Quality

Integrity/Quality

Integrity/Quality

Integrity/Quality

Integrity/Quality

Integrity/Quality

Mobility

This KPI shows the retention period (delay) of a PDCP SDU(DL) inside eNB for non-GBR DRBs (QCI5..9). Time fromreception of IP packet to transmission of first packet over theUu interface

This KPI shows the retention period (delay) of a PDCP SDU(UL) inside eNB. Time starting at the arrival of the PDCP SDUin the eNB and ending at the first transmission of a packetover S1 containing a segment of the SDU

This KPI shows the retransmission ratio for RLC PDUs indownlink direction

This KPI shows the retransmission ratio for RLC PDUs inuplink direction.

This KPI shows the average Received Signal Strength Indicator(RSSI) value for physical UL control channel (PUCCH),measured in the eNB

This KPI shows the average Received Signal Strength Indicator(RSSI) value for physical UL shared channel (PUSCH),measured in the eNB

This KPI shows the Signal to Interference and Noise Ratio(SINR) for the physical UL control channel (PUCCH),measured in the eNB

This KPI shows the Signal to Interference and Noise Ratio(SINR) for the physical UL shared channel (PUSCH),measured in the eNB

This KPI shows the average UE reported Channel Quality Indicator(CQI) value

This KPI shows the average eNB used offset (correction) valuefor Channel Quality Indicators (CQI)

This KPI describes the success ratio for the handover preparation phase, when the source eNB attempts to prepareresources and finally starts to attempt the handover to aneighboring cell within the own eNB

C65

When using the formula, linear scale has to be used with calculations.This means that the dBm values in the counters must be converted to Watts and after the calculation is done,the result must be converted back to dBms.Aggregation of dBm values: P[dBm]=10*lg(P1/1mW) P1= 10^(P[dBm]/10)*1mW

C66

When using the formula, linear scale has to be used with calculations.This means that the dBm values in the counters must be converted to Watts and after the calculation is done,the result must be converted back to dBms. Aggregation of dBm values: P[dBm]=10*lg(P1/1mW) P1= 10^(P[dBm]/10)*1mW

This KPI shows the total number of intra eNB HO preparations Mobility

Mobility

Mobility

This KPI shows the numbe rof intra eNB handover attempts MobilityMobility

Mobility

Mobility

This KPI shows the numbe rof inter eNB X2 based HO preparations Mobility

Mobility

This KPI shows the numbe of inter eNb S1 based HO preparations Mobility

Mobility

Mobility

Mobility

This KPI describes the ratio of a specific intra eNB handoverpreparation failure cause related to total number of intra eNBHO preparations. The source eNB fails to prepare resourcesfor the handover to a neighboring cell within the own eNB.

This KPI describes the ratio of a specific intra eNB handoverpreparation failure cause related to total number of intra eNBHO preparations. The source eNB fails to prepare resourcesfor the handover to a neighboring cell within the own eNB.

This KPI describes the success ratio for the handover executionphase, when the source eNB receives information that theUE successfully is connected to the target cell within own eNB

This KPI describes the ratio of failed intra eNB handoversrelated to all attempted intra eNB handovers. This KPI represents the case of a failed Handover when all UE resources are still allocated for the UE

This KPI describes the total intra eNB HO Success Ratio fromthe HO preparation start until the successful HO execution

This KPI describes the success ratio for the inter eNB X2based handover preparation phase, when the source eNBattempts to prepare resources and finally starts to attempt thehandover to a neighboring cell in a target eNB

This KPI describes the success ratio for the inter eNB S1based handover preparation phase, when the source eNBattempts to prepare resources and finally starts to attempt thehandover to a neighboring cell in a target eNB

This KPI describes the ratio of a specific inter eNB X2 basedhandover preparation failure cause related to total number ofinter eNB X2 based HO preparations. The source eNB fails toprepare resources for the handover to a neighboring cell in atarget eNB



Mobility

Mobility

Mobility

Mobility

This KPI the number of inter eNB X2 based HO attempts Mobility

Mobility

Mobility

Mobility

Mobility

Mobility

Mobility

This KPI describes the ratio of a specific inter eNB S1basedhandover preparation failure cause related to total number ofinter eNB S1 based HO preparations. The source eNB fails toprepare resources for the handover to a neighboring cell in atarget eNB



This KPI describes the success ratio for the inter eNB X2based handover execution phase, when the source eNBreceives information that the UE successfully is connected tothe target cell within target eNB

This KPI describes the success ratio for the inter eNB S1based handover execution phase, when the source eNBreceives information that the UE successfully is connected tothe target cell within target eNB

This KPI shows the number of inetr eNB S1 based HOattempts

This KPI describes the ratio of failed inter eNB X2 based handoversrelated to all attempted inter eNB handovers. This KPIrepresents the case of a failed Handover when all UEresources are still allocated for the UE

This KPI describes the ratio of failed inter eNB S1 based handovers related to all attempted inter eNB handovers. This KPIrepresents the case of a failed Handover when all UEresources are still allocated for the UE

This KPI describes the total inter eNB HO Success Ratio fromthe HO preparation start until the successful HO execution

This KPI describes the total inter eNB S1 based HO SuccessRatio from HO preparation start until successful HO execution

Mobility

Mobility

Mobility

Mobility

Mobility

Usage

Usage

Usage

Usage

Usage

Usage

Usage

Usage

Usage

Usage

Usage

Usage

Usage

Usage

This KPI describes the ratio of a specific CS Fallback Attemptsrelated to all CS Fallback Attempts with redirection via RRCConnection Release



This KPI describes the success ratio for the inter-frequencyHO, when the source eNB receives information that the UEsuccessfully is connected to the target cell within target eNB.The KPI is defined independent of the network topology (intraeNB HO / inter eNB HO) and of the usage of measurement gaps

This KPI describes the success ratio for inter-frequency HOwhen measurement gaps are configured for the UE, when thesource eNB receives information that the UE successfully isconnected to the target cell within target eNB. The KPI isdefined independent of the network topology (intra eNB HO /inter eNB HO)

This KPI shows the average PDCP layer throughput per cell indownlink direction

This KPI shows the average PDCP layer throughput per cell indownlink direction for QCI1 DRBs

This KPI shows the average PDCP layer throughput per cell inuplink direction

This KPI shows the average PDCP layer throughput per cell inuplink direction for QCI1 DRBs

This KPI shows the average RLC layer throughput per cell indownlink direction

This KPI shows the average RLC layer throughput per cell inuplink direction

This KPI shows the average incoming signaling throughput onX2AP layer per eNB

This KPI shows the average outgoing signaling throughput onX2AP layer per eNB

This KPI shows the average incoming user plane data throughputon X2AP layer per eNB

This KPI shows the average outgoing user plane data throughputon X2AP layer per eNB

This KPI shows the average value of the Physical ResourceBlock (PRB) utilization per TTI in downlink direction. The utilizationis defined by the ratio of used to available PRBs per TTI

This KPI shows the average value of the Physical ResourceBlock (PRB) utilization per TTI in uplink direction. The utilizationis defined by the ratio of used to available PRBs per TTI

This KPI shows the ratio of services in a cell being availablefor end-users

This KPI shows the ratio of services in a cell being plannedunavailable for end-users

C97

The LTE_509a and LTE_5110a contain also CS Fallback Attempts for emergency calls reason (as they can be requested both for UE in connected and idle mode) however for emergency calls it is mandatory to provide also a separate KPI (LTE_5111a) to monitor their penetration into the network

C98


C99


Usage

Usage

Usage

Usage

Usage

Usage

Usage

Usage

Usage

Usage

Usage

Usage

Usage

Usage

Usage

This KPI shows the error ratio for IP based incoming traffic Retainability

Accessibility

Reliability

Latency

Latency

This KPI shows the ratio of services in a cell being unplannedunavailable for end-users

This KPI shows Cell Availability, excluding blocked by userstate (BLU)" that gives the percent of available time over timethat should be available

This KPI shows the average number of UE's having data inRLC level buffers during the measurement period per cell fordownlink direction

This KPI shows the average number of UE's having data inRLC level buffers for DRBs of QCI1 during the measurementperiod per cell for downlink direction

This KPI shows the average number of UE's having data inRLC level buffers for non-GBR DRBs during the measurementperiod per cell for downlink direction

This KPI shows the average number of UE's having data inRLC level buffers during the measurement period per cell foruplink direction.

This KPI shows the average number of UE with buffered datain UL per logical channel group id mapped to VoIP (QCI1)DRBs during a measurement period per cell

This KPI shows the average number of UE with buffered datain UL per logical channel group id mapped to non-GBR DRBsduring a measurement period per cell

This KPI shows the maximum number of UE's having data inRLC level buffers during the measurement period per cell fordownlink direction

This KPI shows the maximum number of UE's having data inRLC level buffers during the measurement period per cell foruplink direction

This KPI shows the average number of UE's having one SRBand at least one DRB during the measurement period per eNB

This KPI shows the total data volume for IP based Traffic inincoming direction

This KPI shows the total data volume for IP based Traffic inoutgoing direction

This KPI shows the total throughput for IP based traffic inincoming direction

This KPI shows the total throughput for IP based traffic inoutgoing direction

The service accessibility ratio denotes the probability that the user can establish the necessary bearer (EPS) and access the FTP service successfully

The completed session ratio is the proportion of completed FTP sessions and sessions that were started successfully

It is the time period needed to access the FTP service successfully,from starting the ftp client to the point of time when the first data packet is sent or received

It is the overall duration of the download or upload of reference files from / to the FTP server

Throughput

Latency

Accessibility

Reliability

Integrity/Quality

Latency

Reliability

Latency

Throughput

Latency

Latency

Accessibility

After the connection to the FTP server has been successfully established, the parameter describes the average data transfer rate measured over the data transfer phase

Two alternatives are defined, one being the Post-dial Delay, the other the complete VoIP Session Setup Time.The Post-dial Delay of a VoIP call is defined as the elapsed time between requesting a connection and receiving the first ring tone from the network.The full Session Setup procedure is defined between requesting a connection by the inviting user and receiving a positive response from the called party in a one phase IETF or in a 3-phase 3GPP compliant call setup procedure

It is the probability of successful VoIP call establishments, calculated as the proportion of successful VoIP call setup requests and all call establishment attempts. The VoIP call is not successful if a predefined timer threshold expires, or a network failure inhibited the session setup.Failures due to authentication or authorization errors or to wrong parameter settings are excluded.

It is the percentage of dropped calls against all successfully established calls. It reflects the probability that a VoIP session gets aborted due to some network error. Insufficient network resources are also seen as errors by the end-user.

End-user perceived speech quality expressed as conversational MOS-CQ(MeanOpinion Score) and R factor value

The traversal time of a spoken syllable from the mouth of the speaker to the ears of the listener. It is commonly called mouth-to-ear (m2e) delay.M2e delay values are distinguished for MOC, MTC, and MMC scenarios. The other party in MOC, MOT calls is a fixed VoIP user.

Ratio of voice frames lost, or received with error and of the total number of voice frames sent during the call. Measured in loaded and unloaded network, under different radio conditions. Stationary and mobile user.

Discontinuity of voice media flow (also called “voice gap”) due to handover in UL and DL directions.

The maximum number of concurrent VoIP calls that can be supported by the cell with good voice quality for at least 95% of all users. Voice quality is considered to be good if MOS_CQ ≥ 3.6 during the call.

With Attach, the mobile terminal registers at the LTE network. At theend of the procedure the UE is authenticated, and a default (nGBR) bearer is established.The Attach Time is the interval between the connection request and the acknowledgement of the positive response by the UE

With an explicit Detach request the UE informs the LTE network that it does not want to access the EPS any longer. At the end of the procedure all EPS bearers of the UE are released.The Detach Time is the interval between the Detach Request and the reception of a Detach Accept message by the UE. No Detach Accept is sent by the network if the cause for Detach is switching the UE off.

The Attach Success Rate is defined as the ratio between the number of successful registrations and the number of all requests. This is the probability that a user can attach to the LTE network at any moment of time.

Latency

Latency

Accessibility

Reliability

Mobility

Mobility

Latency

Accessibility

It is the time taken by the LTE network to setup an EPS bearer onrequest by the UE. The EPS bearer can be new (dedicated), or anexisting one (e.g. the default EPS bearer). The latter is needed to reassign Uu radio and S1 bearer resources to the existing EPS bearer of a previously Idle UE.

It is the time taken by the LTE network to set up an EPS bearer onrequest by the P-GW. The EPS bearer has to be created before IPpackets can be sent (DL) to the UE if the UE has no proper EPS bearerfor the given IP packet flow. The network initiated Service RequestTime includes a Paging Time if the UE is idle

This KPI is defined as the ratio between successfully established EPS bearers compared to the overall number of EPS bearer establishment attempts. It corresponds to the probability that a user or the LTE network can establish an EPS bearer at any moment in time.Requests that are terminated by timer expiry (due to the unaccessibility of some LTE resource) are considered as unsuccessful attempts.

It is the ratio between abnormally released bearers and the overallnumber of established EPS bearers. An abnormal release is defined as any EPS bearer termination that was not triggered by the mobile user(from UE side). Thus, it reflects the probability that an established bearer is aborted due to insufficient network resources.Dropping the bearer becomes visible to the end-user if an application service is actively using it. If the application automatically re-establishes the bearer, it remains unnoticed by the user.

It denotes the total time needed for the hand-over procedure as seen by the UE. It begins by receiving a Handover Command from the SeNB and ends by sending the Handover Confirm response to the TeNB by the UE. Its relevance is the discontinuity of the IP packet flow in the user plane that is implied by it(also called service interruption). The value of the HO Procedure Time KPI depends on the hand-over scenario. The following HO scenarios are distinguished(though not directly seen by the UE).

The Handover Success Rate is the ratio between successfully executed (committed)HO procedures and the number of all Handover attempts.

It denotes the total procedure time from starting the paging request in DL and terminating it with the subsequent service request (EPS bearer setup) of the UE after it has been located. Thus, the paging time is per definition the difference between network and UE initiated Service Request Times.

The Paging Failure Rate is the ratio between unsuccessful pagingrequests and the number of all paging attempts initiated by the MME.Retries of the same paging request by the MME are not counted as new attempts. Similarly, multicasting the same request to more than one eNBs (in the UE´s tracking areas) is considered as one attempt

Latency

Throughput

Reliability

Mobility

Reliability

Throughput

Throughput

Reliability

One time paging success ratioOne time TAU success ratio

Success ratio for SAE bare established

The call drop caused by poor RF coverage

RTT in UL is the interval between sending a datagram by the UE &receiving the corresponding reply from an IP peer entity connected to the Gi interface of the P-GW. RTT in DL is the interval between sending a datagram to the UE & receiving the corresponding reply by the IP host (peer entity).

The metric describes the data speed available to one user of the LTE network on UDP/IP level. It is given as the maximum (95%-ile) value that can be observed over a short period of time (e.g. of 1s) and as a mean value that characterizes longer data transfer periods (minutes). Its value distribution over the radio cell is given as a function of the SINR. The maximum value is often referred to in the literature asinstantaneous "Peak Throughput" that is achieved in optimal radio conditions. The user data rate can be given for a single user active in the cell (single user data rate), or to one of several concurrently active users.

This is the ratio between the numbers of lost or corrupted IP packets,and of all IP packets sent. Corrupted IP packets are those that contain bit errors in their headers or in their payload.Packets with "residual", i.e.undetected errors are not counted as lost

The Service Interrupt Time is the interval between the lastsent/received IP packet of a continuous UL/DL data stream in the oldcell and the first sent/received user IP packet in the new cell measured on the UE (also called "user plane break").The value of the KPI depends of the handover scenario

This is the ratio between the numbers of lost or corrupted IP packets,and of all IP packets sent. Corrupted IP packets are those that contain bit errors in their headers or in their payload

The metric describes the UDP/IP data rate achievable by one user. Itcan be given as single user data rate if only one user is active in thecell, or as multi-user data rate for a given number of concurrently active users.

The metric shows the sustainable aggregate throughput of the cell (in UL/DL)available to "n" stationary users distributed uniformly in the cell and running a typical mix of applications. The "cell throughput" is the sum of all bits transported in all radio blocks carrying PDUs (i.e. bits in UL-SCH / DL-SCH transport blocks) during one second. The cell capacity is also given as peak value(called peak cell capacity, or throughput), which is defined as the aggregate throughput of "n" users all located in best radio conditions. The cell throughput value is defined here on PHY level, but could be given for other protocol levels(UDP/IP, PDCP, RLC, MAC), too. When the (peak, average) cell throughput is expressed on UDP/IP level, it corresponds to the (peak, mean) user data rate value at comparable radio conditions

It is the ratio between the numbers of lost or corrupted radio blocks, and of all blocks sent. Corrupted radio blocks are those with bit errors.

Handover within the same MME/S-GW(between eNB)

KPI Logical Formula

sum([EPS_BEARER_SETUP_ATTEMPTS])

S1 init Cont SAtt= initial context setup attempts

S1 SSR=(S1 setup successes / S1 setup attempts)*100%

S1 SattR = S1 setup attemptsS1 SFRCause=(S1 setup failure_x / S1 setup attempts)*100%

S1 SFRCause=(S1 setup failure_x / S1 setup attempts)*100%

E-RAB SSR=(E-RAB setup successes / E-RAB setup attempts)*100%

E-RAB ISSR=(intial E-RAB setup successes /initial E-RAB setup attempts)*100%

E-RAB ASSR=(additional E-RAB setup successes / additionalE-RAB setup attempts)*100%

E-RAB SFRCause=(E-RAB setup failure_x / E-RAB setupattempts)*100%




S1 init Cont SSR=(initial context setup successes / initialcontext setup attempts)*100%

S1 init Cont SFRCause=(initial context setup failure_x / initialcontext setup attempts)*100%




DATA_RB_STP_ATT = DATA_RB_STP_ATT

RB DR=(abnormal RB releases / total RB releases)*100%

RB SR= 100 - RB DR

SIGN_CONN_ESTAB_ATT = SIGN_CONN_ESTAB_ATT_x





UE Con Mod Fail rate =(UE_CONTEXT_MOD_FAIL / UECon Mod Atts) * 100%

DRB SSR=(DRB setup successes /DRB setup attempts)*100%

RCC Con SSR=(RRC connection setup completions /RRC connection requests)*100%

RCC Con SSR EMG=(RRC connection setup completions foremergency calls / RRC connection requests for emergencycalls)*100%

Paging Records = transmitted RRC paging records

S1 SFR=(RRC connection setup failure_x /RRC connection requests)*100%




Paging DCR=(discarded RRC paging records /transmitted RRC paging records)*100%

E-RAB DR RAN=(abnormal E-RAB release requests / all ERABrelease commands)*100%

E-RAB DRCause=(abnormal E-RAB release request_x / allE-RAB release commands)*100%





E-RAB NRR UP=(normal E-RAB releases user perspective /all E-RAB releases)*100%

LatencyAvgDL = PDCP SDU delay on DL DTCH Mean

E-RAB NRR RAN=(normal E-RAB releases RAN view/ all ERABreleases)*100%





E-RAB DR UP=(abnormal E-RAB release requests, user perspective/ all E-RAB releases )*100%

S1 init Cont SFRCause=(initial context setup failure_x / initial context setup attempts)*100%




S1 SFRCause=(S1 setup failure_x / S1 setupattempts)*100%

S1 SFRCause=(S1 setup failure_x / S1 setupattempts)*100%

IP IN ER = (incoming erroneous IP packets) /(total incoming IP packets)

LatencyAvgDL=PDCP SDU delay on DL DTCH Mean forQCI1 DRBs

LatencyAvgUL = PDCP SDU delay on UL DTCH Mean

AVG CQI Offset= average of measured CQI offset values

LatencyAvgDLnonGBR=PDCP SDU delay on DL DTCHMean for non GBR DRBs

DL RLC PDU ReTrR =(number of retrans. RLC PDUs) /(number all trans RLC PDUs)

UL RLC PDU ReTrR =(number of received duplicated RLC PDUs) /(number all received RLC PDUs)

AVG RSSI PUCCH= average of measured RSSI values forPUCCH

AVG RSSI PUSCH = average of measured RSSI values forPUSCH

AVG SINR PUCCH= average of measured SINR values forPUCCH

AVG SINR PUSCH= average of measured SINR values forPUSCH

AVG CQI= sum(number of hits in class_x * x) /sum(total number of hits over all classes)x = 0, …, 15

Intra HO prep SR =(number of successful intra eNB HO prep)/(total number of intra enB HO preparations)*100%=(number of intra eNB HO attempts) /(total number of intra eNB HO preparations)*100%

Intra HO preps = (total number of intra eNB HO preparations)

Intra HO Att =(number of intra eNB HO attempts)

Intra HO prep FRCause =(number of intra eNB HO prepfailure_x) / (total number of intra enB HO preparations)*100%

Intra HO prep FRCause =(number of intra eNB HO prepfailure_x) / (total number of intra enB HO preparations)*100%

Intra HO SR =(number of successful intra eNB HOs) /(number of intra eNB HO attempts)*100%

Intra HO FR =(number of unsuccessful intra eNB HOs) /(number of intra eNB HO attempts)*100%

Intra tot HO SR = (intra eNB HO prep successes) /(intra eNB HO preparations) * (intra eNB HO successes) /(intra eNB HO attempts) *100% = (intra eNB HO attempts) /(intra eNB HO preparations) * (intra eNB HO successes) /(intra eNB HO attempts)*100% = (intra eNB HO successes) /(intra eNB HO preparations)*100%

Inter X2 based HO prep SR =(number of successful inter eNBX2 based HO prep) /(total number of inter eNB X2 based HO preparations)*100%=(number of inter eNB X2 based HO attempts) /(total number of inter eNB X2 based HO preparations)*100%

Inter X2 based HO preparations =(total number of inter eNB X2 based HO preparations)

Inter S1 based HO prep SR =(number of successful inter eNBS1 based HO prep) /(total number of inter eNB S1 based HO preparations)*100%=(number of inter eNB S1 based HO attempts) /(total number of inter eNB S1 based HO preparations)*100%

Inter S1 based HO preparations =(total number of inter eNB S1 based HO preparations)

Inter X2 based HO prep FR =(number of inter eNB X2 based HO prep failure_x) /(total number of inter eNB X2 based HO preparations)*100%



Inter S1 based HO prep FDR =(number of inter eNB S1 basedHO prep failure_x) / (total number of inter eNB S1 based HOpreparations)*100%



Inter X2 based HO SR =(number of successful inter eNB X2based HOs) /(number of inter eNB X2 based HO attempts)*100%

Inter X2 based HO Att =(number of inter eNB X2 based HO attempts)

Inter S1 based HO SR =(number of successful inter eNB S1based HOs) /(number of inter eNB S1 based HO attempts)*100%

Inter S1 based HO Att =(number of inter eNB S1 based HO attempts)

Inter X2 based HO FR =(number of unsuccessful inter eNB X2based HOs) /(number of inter eNB X2 based HO attempts)*100%

Inter S1 based HO FR =(number of unsuccessful inter eNB S1based HOs) /(number of inter eNB S1 based HO attempts)*100%

Inter tot X2 based HO SR=(inter eNB X2 based HO prep successes) /(inter eNB X2 based HO preparations) *(inter eNB X2 based HO successes) /(inter eNB X2 based HO attempts) *100%=(inter eNB X2 based HO attempts) /(inter eNB X2 based HO preparations) *(inter eNB X2 based HO successes) /(inter eNB X2 based HO attempts)*100%=(inter eNB X2 based HO successes) /(inter eNB X2 based HO preparations)*100%

Inter tot S1 based HO SR=(inter eNB S1 based HO prep successes) /(inter eNB S1 based HO preparations) *(inter eNB S1 based HO successes) /(inter eNB S1 based HO attempts) *100%=(inter eNB S1 based HO attempts) /(inter eNB S1 based HO preparations) *(inter eNB S1 based HO successes) /(inter eNB S1 based HO attempts)*100%=(inter eNB S1 based HO successes) /(inter eNB S1 based HO preparations)*100%

AVG DL PDCP CELL THP = average PDCP cell throughput DL

AVG UL PDCP CELL THP = average PDCP cell throughput UL

AVG DL PRBs = (average (used/available) DL PRBs per TTI)

AVG UL PRBs = (average (used/available)UL PRBs per TTI)

CSFB AttDR=( CS Fallback Attempts _x / CS FallbackAttempts all)*100%



Inter Frequency HO SR =(number of successful Inter-Frequency HOs) /(number of Inter-Frequency HO attempts)*100%

Inter Frequency HO SR = (number of successful Inter-Frequency HOs measurement gap assisted) /(number of Inter-Frequency HO attempts measurement gapassisted)*100%

AVG DL PDCP CELL THP QCI1= average PDCP cell throughputDL for QCI1 DRBs

AVG UL PDCP CELL THP QCI1= average PDCP cell throughputUL for QCI1 DRBs

AVG DL RLC CELL THP =(DL transmitted RLC PDU volume)*8 /(MEASUREMENT_DURATION)*60

AVG UL RLC CELL THP= (UL received RLC PDU volume)*8 /(MEASUREMENT_DURATION)*60

AVG IN X2 SIG THP = (incoming X2AP signaling volume)*8 /(MEASUREMENT_DURATION)*60

AVG OUT X2 SIG THP = (outgoing X2AP signaling volume)*8 /(MEASUREMENT_DURATION)*60

AVG X2 DAT THP IN=(incoming X2AP user plane data volume)*8/1000 /(MEASUREMENT_DURATION)*60

AVG X2 DAT THP OUT=(outgoing X2AP user plane data volume)*8/1000 /(MEASUREMENT_DURATION)*60

CELL AVR=(time of cell is available for services) /(total measured time)=(number of samples when cell is available) /(number of all samples)

CELL PL UAVR= (time of cell is planned unavailable for services)/ (total measured time)=(number of samples when cell is planned unavailable) /(number of all samples)

ACT UE ENB = (average number of active UEs per eNB)

IP VOL IN=(incoming IP octets [kB]) / 1000

IP VOL UL=(outgoing IP octets [kB]) / 1000

FtpSessionTime[s] = t_sessionend-t_sessionstart

CELL UPL UAVR=(time of cell is unplanned unavailable forservices) / (total measured time)= (number of samples when cell is unplanned unavailable) /(number of all samples)

CELL AVR BLU =(number of samples when cell is available) /(number of all samples number of samples when cell isplanned unavailable )

ACT UE D AVG DL = ( DL average number of active UEs withdata in buffer per cell)

ACT UE D AVG DL QCI1 =( DL average number of active UEswith data in buffer for DRBs of QCI1 per cell)

ACT UE D AVG DL non GBR=( DL average number of activeUEs with data in buffer for non-GBR DRBs per cell)

ACT UE D AVG UL = (UL average number of active UEs withdata in buffer per cell)

ACT UE D AVG UL QCI1 =(UL average number of active UEswith buffered data in UL for DRBs of QCI1)

ACT UE D AVG UL non GBR =(UL average number of activeUEs with buffered data in UL for non GBR DRBs)

ACT UE D MAX DL = ( DL maximum number of active UEswith data in buffer per cell)

ACT UE D MAX UL= (UL maximum number of active UEs withdata in buffer per cell)

IP THP DL = (incoming IP octets [kB])*8 /measurement duration [sec]

IP THP UL = (outgoing IP octets [kB])*8 /measurement duration [sec]

IP IN ER = (incoming erroneous IP packets) /(total incoming IP packets)

FtpCmdSR= number_of(successful_ftp_commands\number_of(total_ftp_commands)*100

FtpSessionSR=number_of(completed_sessions)\number_of(sucessfully_started_sessions)*100

FtpServiceAccessTime[s]=t_content sent or received-t_ftp command started

Attach Time [ms] = tAttach Complete – tAttach Request

FtpMeanDataRateUL/DL = {transffered_data_volume_UL/DL[bytes]*8}\{transfer_time[s]}

VoIPCallSetupTime [s] = t Connection Established − t Push Dial Button

VoIPCallSR ={ number_of (successful_calls)}\{number_of (call_setup_requests)}*100

VoIPCallDR = {number_of (dropped_calls)}\{number_of (successful_calls)}*100


VoIPFER = {number_of (lost_corrupted_discarded_frames)}\{number_of (all_frames_sent)}*100

Voice Interrupt Time [ms] = tfirst packet TeNB – tlast packet SeNB

LTENwAttSR = (number_of_successful_attachments)\(number_of_all_attempts)*100%

Service Request Time [ms] = tRRC_Reconfig – tRRC_Request

Service Request Time [s] = tRRC_Reconfig – tRRC_Request

Handover Procedure Time [ms] = tHO_Confirm – tHO_Command

Paging Time [s] = tSRT network = initiated – tSRT UE initiated

EPSSR =[number_of(RRC_CONN_RECONFIGURATION_COMPLETE)]\[number_of(RRC_CONNECTION_REQUEST)]*100

EPSBearerD R = [number_of(dropped_calls)]\[number_of(successful_calls)]*100

HOSR = [number_of(Handover_Confirm)]\[number_of(Handover_Request)]*100

PagingFR = [number_of(Paging_Failures)]\[number_of(Paging_Attempts)]*100

Rate={100}*[L.Paging.UU.Succ]/[L.Paging.UU.Att]rate=100*S1_mode_TAU_success_times/S1_mode_TAU_times

Round Trip Time [ms] = tICMP = Echo Reply – tICMP Echo Request

UserDataRate = (transferred_data_volume[bytes]*8\(transfer_time[s])*1000

PLR = [number_of(lost_corrupted_packets)]\[number_of(all_packets_sent)]*100

Service Interrupt Time [ms] = tfirst = packet to/from TeNB – tlast packet to/from SeNB

RBPLR = [number_of(lost_corrupted_packets)]\[number_of(all_packet_sent)]*100

RBUserDataRate = (transferred_data_volume [bytes])*8\(transfer_time [s])* 10–6

CellThroughput = (transferred_data_volume [bytes])*8\(transfer_time [s])* 10–6

Residual BLER = (number_of_lost_corrupted_radio_blocks)\(number_of_all_radio_blocks_sent)*100

100* SAE_bearer_setup_success_times/ SAE_bearer_setup_request_times

Counter ID KPI Formula with Counters Names

100*sum[M8006C1] /sum[M8006C0]

sum([M8006C0]) sum([EPS_BEARER_SETUP_ATTEMPTS])100* sum([M8006C2]) / sum([M8006C0])

100* sum([M8006C3]) / sum([M8006C0])

100* sum([M8006C4]) / sum([M8006C0])

100* sum([M8006C5]) / sum([M8006C0])

100*sum([M8000C1]) / sum([M8000C0])

sum([M8000C0]) sum([INI_CONT_STP_REQ])100*sum([M8000C2]) / sum([M8000C0])

100*sum([M8000C3]) / sum([M8000C0])

100*sum([M8000C4]) / sum([M8000C0])

100*sum([M8000C5]) / sum([M8000C0])

100*sum([M8000C7]) / sum([M8000C6]) 100*sum([S1_SETUP_SUCC]) / sum([S1_SETUP_ATT])

sum([M8000C6]) sum([S1_SETUP_ATT])100*sum([M8000C8]) / sum([M8000C6])

100*sum([M8000C9]) / sum([M8000C6])

100*sum([EPS_BEARER_SETUP_COMPLETIONS]) /sum([EPS_BEARER_SETUP_ATTEMPTS])

100*sum([M8006C35]+ [M8006C36]) /sum([M8006C17]+[M8006C18])

100*sum([EPS_BEARER_STP_COM_INI_QCI1+EPS_BEAR_STP_COM_INI_NON_GBR])/sum([EPS_BEARER_STP_ATT_INI_QCI_1+EPS_BEAR_STP_ATT_INI_NON_GBR])

100*sum([M8006C1] - [M8006C35] - [M8006C36])/sum([M8006C0] - [M8006C17] - [M8006C18])

100*sum([EPS_BEARER_SETUP_COMPLETIONS -EPS_BEARER_STP_COM_INI_QCI1 -EPS_BEAR_STP_COM_INI_NON_GBR]) /sum([EPS_BEARER_SETUP_ATTEMPTS -EPS_BEARER_STP_ATT_INI_QCI_1-EPS_BEAR_STP_ATT_INI_NON_GBR])

100*sum([EPS_BEARER_SETUP_FAIL_RNL]) /sum ([EPS_BEARER_SETUP_ATTEMPTS])

100* sum([EPS_BEARER_SETUP_FAIL_TRPORT]) /sum([EPS_BEARER_SETUP_ATTEMPTS])

100* sum([EPS_BEARER_SETUP_FAIL_RESOUR]) /sum([EPS_BEARER_SETUP_ATTEMPTS])

100* sum([EPS_BEARER_SETUP_FAIL_OTH]) /sum([EPS_BEARER_SETUP_ATTEMPTS])

100*sum([INI_CONT_STP_COMP]) /sum([INI_CONT_STP_REQ])

100*sum([INI_CONT_STP_FAIL_RNL]) /sum([INI_CONT_STP_REQ])

100*sum([INI_CONT_STP_FAIL_TRPORT]) /sum([INI_CONT_STP_REQ])

100*sum([INI_CONT_STP_FAIL_RESOUR]) /sum([INI_CONT_STP_REQ])

100*sum([INI_CONT_STP_FAIL_OTHER]) /sum([INI_CONT_STP_REQ])

100*sum([S1_SETUP_FAIL_NO_RESP]) /sum([S1_SETUP_ATT])

100*sum([S1_SETUP_FAIL_IND_BY_MME]) /sum([S1_SETUP_ATT])

100*sum([M8000C25]) / sum([M8000C23])

DATA_RB_STP_ATT = sum([M8007C0]) DATA_RB_STP_ATT = sum([DATA_RB_STP_ATT])100*sum([M8007C1]) / sum([M8007C0])

RB SR= 100 - LTE_5004

sum([M8013C17]) sum ([SIGN_CONN_ESTAB_ATT_MO_S])

sum([M8013C18]) sum([SIGN_CONN_ESTAB_ATT_MT])

sum([M8013C19]) sum([SIGN_CONN_ESTAB_ATT_MO_D])

sum([M8013C20]) sum([SIGN_CONN_ESTAB_ATT_OTHERS])

sum([M8013C21]) sum([SIGN_CONN_ESTAB_ATT_EMG])

100*sum([M8013C26]) / sum([M8013C21])

100*sum([([UE_CONTEXT_MOD_FAIL]) /sum([UE_CONTEXT_MOD_ATT])

100*sum([DATA_RB_STP_COMP]) /sum([DATA_RB_STP_ATT])

100*sum([M8007C5])+([M8007C6]) /sum([M8007C3]+([M8007C4]+[M8007C5]+[M8007C13]+[M8007C6])

100*sum([RB_REL_REQ_RNL]+[RB_REL_REQ_OTHER]) /sum([RB_REL_REQ_NORM_REL]+[RB_REL_REQ_DETACH_PROC]+[RB_REL_REQ_RNL]+[RB_REL_REQ_RNL_REDIR]+[RB_REL_REQ_OTHER])

RB SR= 100 - (100*sum([M8007C5])+([M8007C6]) /sum([M8007C3]+([M8007C4]+[M8007C5]+[M8007C13]+[M8007C6]))

100*sum([M8013C5]) /sum([M8013C17]+[M8013C18]+[M8013C19]+[M8013C20])

100*sum([SIGN_CONN_ESTAB_COMP]) /sum([SIGN_CONN_ESTAB_ATT_MO_S]+[SIGN_CONN_ESTAB_ATT_MT]+[SIGN_CONN_ESTAB_ATT_MO_D]+[SIGN_CONN_ESTAB_ATT_OTHERS])

100*sum([SIGN_CONN_ESTAB_COMP_EMG]) /sum([SIGN_CONN_ESTAB_ATT_EMG])

100*sum([M8008C2]) / sum([M8008C1])

sum([M8008C1]) sum ([RRC_PAGING_REQUESTS])


100*sum([SIGN_EST_F_RRCCOMPL_MISSING]) /sum([SIGN_CONN_ESTAB_ATT_MO_S]+[SIGN_CONN_ESTAB_ATT_MT]+[SIGN_CONN_ESTAB_ATT_MO_D]+[SIGN_CONN_ESTAB_ATT_OTHERS])


100*sum([SIGN_EST_F_RRCCOMPL_ERROR]) /sum([SIGN_CONN_ESTAB_ATT_MO_S]+[SIGN_CONN_ESTAB_ATT_MT]+[SIGN_CONN_ESTAB_ATT_MO_D]+[SIGN_CONN_ESTAB_ATT_OTHERS])


100*sum([SIGN_CONN_ESTAB_FAIL_RRMRAC]) /sum([SIGN_CONN_ESTAB_ATT_MO_S]+[SIGN_CONN_ESTAB_ATT_MT]+[SIGN_CONN_ESTAB_ATT_MO_D]+[SIGN_CONN_ESTAB_ATT_OTHERS])

100*sum([SIGN_CONN_ESTAB_FAIL_EMG]) /sum([SIGN_CONN_ESTAB_ATT_MO_S]+[SIGN_CONN_ESTAB_ATT_MT]+[SIGN_CONN_ESTAB_ATT_MO_D]+[SIGN_CONN_ESTAB_ATT_OTHERS])

100*sum([DISC_RRC_PAGING]) /sum ([RRC_PAGING_REQUESTS])

100*sum([M8006C12]+[M8006C14]+[M8006C13])/sum([M8006C6]+[M8006C7]+[M8006C8]+ [M8006C9] +[M8006C15]+ [M8006C10] + [M8006C12] +[M8006C14]+[M8006C13])

100*sum([ENB_EPS_BEARER_REL_REQ_RNL]+[ENB_EPS_BEARER_REL_REQ_TNL]+[ENB_EPS_BEARER_REL_REQ_OTH]) /sum([EPC_EPS_BEARER_REL_REQ_NORM]+[EPC_EPS_BEARER_REL_REQ_DETACH]+[EPC_EPS_BEARER_REL_REQ_RNL]+[EPC_EPS_BEARER_REL_REQ_OTH]+[ENB_EPSBEAR_REL_REQ_RNL_REDIR]+[ENB_EPS_BEARER_REL_REQ_NORM] +[ENB_EPS_BEARER_REL_REQ_RNL]+[ENB_EPS_BEARER_REL_REQ_TNL]+[ENB_EPS_BEARER_REL_REQ_OTH])

100 * sum([M8006C12])/ sum([M8006C6] + [M8006C7] +[M8006C8] + [M8006C9] + [M8006C15] + [M8006C10] +[M8006C12] + [M8006C14] + [M8006C13])

100*sum([ENB_EPS_BEARER_REL_REQ_RNL]) /sum([EPC_EPS_BEARER_REL_REQ_NORM]+[EPC_EPS_BEARER_REL_REQ_DETACH]+[EPC_EPS_BEARER_REL_REQ_RNL]+[EPC_EPS_BEARER_REL_REQ_OTH]+[ENB_EPSBEAR_REL_REQ_RNL_REDIR]+[ENB_EPS_BEARER_REL_REQ_NORM] +[ENB_EPS_BEARER_REL_REQ_RNL]+[ENB_EPS_BEARER_REL_REQ_TNL]+[ENB_EPS_BEARER_REL_REQ_OTH])

100 * sum([M8006C14])/ sum([M8006C6] + [M8006C7] +[M8006C8] + [M8006C9] + [M8006C15] + [M8006C10] +[M8006C12] + [M8006C14] + [M8006C13])

100*sum([ENB_EPS_BEARER_REL_REQ_TNL]) /sum([EPC_EPS_BEARER_REL_REQ_NORM]+[EPC_EPS_BEARER_REL_REQ_DETACH]+[EPC_EPS_BEARER_REL_REQ_RNL]+[EPC_EPS_BEARER_REL_REQ_OTH]+[ENB_EPSBEAR_REL_REQ_RNL_REDIR]+[ENB_EPS_BEARER_REL_REQ_NORM] +[ENB_EPS_BEARER_REL_REQ_RNL]+[ENB_EPS_BEARER_REL_REQ_TNL]+[ENB_EPS_BEARER_REL_REQ_OTH])

100*sum([M8006C13])/ sum([M8006C6] + [M8006C7] +[M8006C8] + [M8006C9] + [M8006C15] + [M8006C10] +[M8006C12] + [M8006C14] + [M8006C13])

100*sum([ENB_EPS_BEARER_REL_REQ_OTH]) /sum([EPC_EPS_BEARER_REL_REQ_NORM]+[EPC_EPS_BEARER_REL_REQ_DETACH]+[EPC_EPS_BEARER_REL_REQ_RNL]+[EPC_EPS_BEARER_REL_REQ_OTH]+[ENB_EPSBEAR_REL_REQ_RNL_REDIR]+[ENB_EPS_BEARER_REL_REQ_NORM] +[ENB_EPS_BEARER_REL_REQ_RNL]+[ENB_EPS_BEARER_REL_REQ_TNL]+[ENB_EPS_BEARER_REL_REQ_OTH])


100*sum([EPC_EPS_BEARER_REL_REQ_RNL]) /sum([EPC_EPS_BEARER_REL_REQ_NORM]+[EPC_EPS_BEARER_REL_REQ_DETACH]+[EPC_EPS_BEARER_REL_REQ_RNL]+[EPC_EPS_BEARER_REL_REQ_OTH] +[ENB_EPSBEAR_REL_REQ_RNL_REDIR]+[ENB_EPS_BEARER_REL_REQ_NORM] +[ENB_EPS_BEARER_REL_REQ_RNL]+[ENB_EPS_BEARER_REL_REQ_TNL]+[ENB_EPS_BEARER_REL_REQ_OTH])


100*sum([EPC_EPS_BEARER_REL_REQ_OTH]) /sum([EPC_EPS_BEARER_REL_REQ_NORM]+[EPC_EPS_BEARER_REL_REQ_DETACH]+[EPC_EPS_BEARER_REL_REQ_RNL]+[EPC_EPS_BEARER_REL_REQ_OTH] +[ENB_EPSBEAR_REL_REQ_RNL_REDIR]+[ENB_EPS_BEARER_REL_REQ_NORM]+[ENB_EPS_BEARER_REL_REQ_RNL]+[ENB_EPS_BEARER_REL_REQ_TNL]+[ENB_EPS_BEARER_REL_REQ_OTH])

100*sum([M8006C6]+[M8006C7]+[M8006C15]+[M8006C10]) / sum([M8006C6]+[M8006C7]+[M8006C8]+[M8006C9] + [M8006C15]+ [M8006C10] + [M8006C12]+[M8006C14] +[M8006C13])

100*sum([EPC_EPS_BEARER_REL_REQ_NORM]+EPC_EPS_BEARER_REL_REQ_DETACH]+[ENB_EPSBEAR_REL_REQ_RNL_REDIR]+[ENB_EPS_BEARER_REL_REQ_NORM]) /sum([EPC_EPS_BEARER_REL_REQ_NORM]+[EPC_EPS_BEARER_REL_REQ_DETACH]+[EPC_EPS_BEARER_REL_REQ_RNL]+[EPC_EPS_BEARER_REL_REQ_OTH]+[ENB_EPSBEAR_REL_REQ_RNL_REDIR]+[ENB_EPS_BEARER_REL_REQ_NORM] +[ENB_EPS_BEARER_REL_REQ_RNL]+[ENB_EPS_BEARER_REL_REQ_TNL]+[ENB_EPS_BEARER_REL_REQ_OTH])

100* sum([M8006C2]) / sum([M8006C0])

100* sum([M8006C3]) / sum([M8006C0])

100* sum([M8006C4]) / sum([M8006C0])

100* sum([M8006C5]) / sum([M8006C0])

100*sum([M8000C2]) / sum([M8000C0])

100*sum([M8000C3]) / sum([M8000C0])

100*sum([M8000C4]) / sum([M8000C0])

100*sum([M8000C5]) / sum([M8000C0])

100*sum([M8000C8]) / sum([M8000C6])

100*sum([M8000C9]) / sum([M8000C6])

sum([M51120C0]) / sum([M51120C4])*100%

avg([M8001C2]) avg([PDCP_SDU_DELAY_DL_DTCH_MEAN])

avg([M8001C269]) avg([PDCP_RET_DL_DEL_MEAN_QCI_1])

100*sum([M8006C10]+[M8006C15]+[M8006C6]+[M8006C7]+[M8006C8]+[M8006C9]) /sum([M8006C6]+[M8006C7]+[M8006C8]+ [M8006C9] +[M8006C15]+ [M8006C10] + [M8006C12] +[M8006C14]+[M8006C13])

100*sum([ENB_EPS_BEARER_REL_REQ_NORM]+ENB_EPS_BEARER_REL_REQ_RNL_REDIR]+[EPC_EPS_BEARER_REL_REQ_NORM]+[EPC_EPS_BEARER_REL_REQ_DETACH]+[EPC_EPS_BEARER_REL_REQ_RNL]+[EPC_EPS_BEARER_REL_REQ_OTH]) /sum([EPC_EPS_BEARER_REL_REQ_NORM]+[EPC_EPS_BEARER_REL_REQ_DETACH]+[EPC_EPS_BEARER_REL_REQ_RNL]+[EPC_EPS_BEARER_REL_REQ_OTH]+[ENB_EPSBEAR_REL_REQ_RNL_REDIR]+[ENB_EPS_BEARER_REL_REQ_NORM] +[ENB_EPS_BEARER_REL_REQ_RNL]+[ENB_EPS_BEARER_REL_REQ_TNL]+[ENB_EPS_BEARER_REL_REQ_OTH])

sum([EPS_BEARER_SETUP_FAIL_RNL]) /sum ([EPS_BEARER_SETUP_ATTEMPTS])

100* sum([EPS_BEARER_SETUP_FAIL_TRPORT]) /sum([EPS_BEARER_SETUP_ATTEMPTS])

100* sum([EPS_BEARER_SETUP_FAIL_RESOUR]) /sum([EPS_BEARER_SETUP_ATTEMPTS])

100* sum([EPS_BEARER_SETUP_FAIL_OTH]) /sum([EPS_BEARER_SETUP_ATTEMPTS])

100*sum([M8006C8]+[M8006C9] +[M8006C12]+[M8006C14]+ [M8006C13]) /sum([M8006C6]+[M8006C7]+[M8006C8]+ [M8006C9] +[M8006C15]+ [M8006C10] + [M8006C12] +[M8006C14]+[M8006C13])

100*sum([EPC_EPS_BEARER_REL_REQ_RNL]+[EPC_EPS_BEARER_REL_REQ_OTH] +[ENB_EPS_BEARER_REL_REQ_RNL]+[ENB_EPS_BEARER_REL_REQ_TNL]+[ENB_EPS_BEARER_REL_REQ_OTH]) /sum([EPC_EPS_BEARER_REL_REQ_NORM]+[EPC_EPS_BEARER_REL_REQ_DETACH]+[EPC_EPS_BEARER_REL_REQ_RNL]+[EPC_EPS_BEARER_REL_REQ_OTH] +[ENB_EPSBEAR_REL_REQ_RNL_REDIR]+[ENB_EPS_BEARER_REL_REQ_NORM] +[ENB_EPS_BEARER_REL_REQ_RNL]+[ENB_EPS_BEARER_REL_REQ_TNL]+[ENB_EPS_BEARER_REL_REQ_OTH])

100*sum([INI_CONT_STP_FAIL_RNL]) /sum([INI_CONT_STP_REQ])

100*sum([INI_CONT_STP_FAIL_TRPORT]) /sum([INI_CONT_STP_REQ])

100*sum([INI_CONT_STP_FAIL_RESOUR]) /sum([INI_CONT_STP_REQ])

100*sum([INI_CONT_STP_FAIL_OTHER]) /sum([INI_CONT_STP_REQ])

100*sum([S1_SETUP_FAIL_NO_RESP]) /sum([S1_SETUP_ATT])

100*sum([S1_SETUP_FAIL_IND_BY_MME]) /sum([S1_SETUP_ATT])

sum([ifInErrors15]) /sum([ifInPackets15])*100%

avg([M8001C270]) avg([PDCP_RET_DL_DEL_MEAN_NON_GBR])

avg([M8001C5]) avg([PDCP_SDU_DELAY_UL_DTCH_MEAN])

sum([M8001C143]) / sum[M8001C142])*100%

avg([M8005C2]) avg([RSSI_PUCCH_AVG])

avg([M8005C5]) avg([RSSI_PUSCH_AVG])

avg([M8005C92]) avg([SINR_PUCCH_AVG])

avg([M8005C95]) avg([SINR_PUSCH_AVG])

avg([M8010C54])/1000 avg([CQI_OFF_MEAN])/1000

100*sum([M8009C6]) / sum([M8009C2])

sum([M8001C138]) /sum([M8001C137]+[M8001C138])*100%

sum([RLC_PDU_RE_TRANS]) /sum([RLC_PDU_FIRST_TRANS]+[RLC_PDU_RE_TRANS])*100%

sum([UL_RLC_PDU_DUPL_REC]) /sum([UL_RLC_PDU_REC_TOT])*100%

sum(1*[M8010C37]+2*[M8010C38] + 3*[M8010C39] + 4*[M8010C40] +5*[M8010C41] + 6*[M8010C42] + 7*[M8010C43] +8*[M8010C44] + 9*[M8010C45] + 10*[M8010C46]+11*[M8010C47] + 12*[M8010C48] + 13*[M8010C49]+14*[M8010C50] + 15*[M8010C51]) /sum([M8010C36] + [M8010C37] + [M8010C38] + [M8010C39] +[M8010C40] + [M8010C41] + [M8010C42] +[M8010C43] + [M8010C44] + [M8010C45] +[M8010C46] + [M8010C47] + [M8010C48] +[M8010C49] + [M8010C50] + [M8010C51])

sum(1*[UE_REP_CQI_LEVEL_01]+2*[UE_REP_CQI_LEVEL_02]+3*[UE_REP_CQI_LEVEL_03]+4*[UE_REP_CQI_LEVEL_04]+5*[UE_REP_CQI_LEVEL_05]+6*[UE_REP_CQI_LEVEL_06]+7*[UE_REP_CQI_LEVEL_07]+8*[UE_REP_CQI_LEVEL_08]+9*[UE_REP_CQI_LEVEL_09]+10*[UE_REP_CQI_LEVEL_10]+11*[UE_REP_CQI_LEVEL_11]+12*[UE_REP_CQI_LEVEL_12]+13*[UE_REP_CQI_LEVEL_13]+14*[UE_REP_CQI_LEVEL_14]+15*[UE_REP_CQI_LEVEL_15]) /sum([UE_REP_CQI_LEVEL_00]+[UE_REP_CQI_LEVEL_01]+[UE_REP_CQI_LEVEL_02]+[UE_REP_CQI_LEVEL_03]+[UE_REP_CQI_LEVEL_04]+[UE_REP_CQI_LEVEL_05]+[UE_REP_CQI_LEVEL_06]+[UE_REP_CQI_LEVEL_07]+[UE_REP_CQI_LEVEL_08]+[UE_REP_CQI_LEVEL_09]+[UE_REP_CQI_LEVEL_10]+[UE_REP_CQI_LEVEL_11]+[UE_REP_CQI_LEVEL_12]+[UE_REP_CQI_LEVEL_13]+[UE_REP_CQI_LEVEL_14]+[UE_REP_CQI_LEVEL_15])

100*sum([ATT_INTRA_ENB_HO]) /sum([INTRA_ENB_HO_PREP])

sum([M8009C2]) sum([INTRA_ENB_HO_PREP])

100*sum([M8009C3]) / sum([M8009C2])

100*sum([M8009C5]) / sum([M8009C2])

100*sum([M8009C7]) / sum([M8009C6])

sum([M8009C6]) sum([ATT_INTRA_ENB_HO])100*sum([M8009C8]) / sum([M8009C6])

100*sum([M8009C7]) / sum([M8009C2])

100*sum([M8014C6]) / sum([M8014C0])

sum([M8014C0]) sum ([INTER_ENB_HO_PREP])

100*sum([M8014C18]) / sum([M8014C14])

sum([M8014C14]) sum ([INTER_ENB_S1_HO_PREP])

100*sum([M8014C2]) / sum([M8014C0])

100*sum([M8014C3]) / sum([M8014C0])

100*([M8014C5]) / sum([M8014C0])

100*sum([FAIL_ENB_HO_PREP_AC]) /sum([INTRA_ENB_HO_PREP])

100*sum([FAIL_ENB_HO_PREP_OTH]) /sum([INTRA_ENB_HO_PREP])

100*sum([SUCC_INTRA_ENB_HO]) /sum([ATT_INTRA_ENB_HO])

100*sum([ENB_INTRA_HO_FAIL]) /sum([ATT_INTRA_ENB_HO])

100*sum([SUCC_INTRA_ENB_HO]) /sum([INTRA_ENB_HO_PREP])

100*sum([ATT_INTER_ENB_HO]) /sum ([INTER_ENB_HO_PREP])

100*sum([INTER_ENB_S1_HO_ATT]) /sum ([INTER_ENB_S1_HO_PREP])

100*sum([FAIL_ENB_HO_PREP_TIME]) /sum([INTER_ENB_HO_PREP])

100*sum([FAIL_ENB_HO_PREP_AC]) /sum ([INTER_ENB_HO_PREP])

100*sum([FAIL_ENB_HO_PREP_OTHER]) /sum ([INTER_ENB_HO_PREP])

100*sum([M8014C15]) / sum([M8014C14])

100*sum([M8014C16]) / sum([M8014C14])

100*sum([M8014C17]) / sum([M8014C14])

100*sum([M8014C7]) / sum([M8014C6])

sum([M8014C6]) sum ([ATT_INTER_ENB_HO])

100*sum([M8014C19]) / sum([M8014C18])

sum([M8014C18]) sum ([INTER_ENB_S1_HO_ATT])

100*sum([M8014C8]) / sum([M8014C6])

100*sum([M8014C20]) / sum([M8014C18])

100*sum([M8014C7]) / sum([M8014C0])

100*sum([M8014C19]) / sum([M8014C14])

100*sum([INTER_S1_HO_PREP_FAIL_TIME]) /sum ([INTER_ENB_S1_HO_PREP])

100*sum([INTER_S1_HO_PREP_FAIL_NORR]) /sum([INTER_ENB_S1_HO_PREP])

100*sum([INTER_S1_HO_PREP_FAIL_OTHER]) /sum ([INTER_ENB_S1_HO_PREP])

100*sum([SUCC_INTER_ENB_HO]) /sum ([ATT_INTER_ENB_HO])

100*sum([INTER_ENB_S1_HO_SUCC]) /sum ([INTER_ENB_S1_HO_ATT])

100*sum([INTER_ENB_HO_FAIL]) /sum ([ATT_INTER_ENB_HO])

100*sum([INTER_ENB_S1_HO_FAIL]) /sum ([INTER_ENB_S1_HO_ATT])

100*sum([SUCC_INTER_ENB_HO]) /sum([INTER_ENB_HO_PREP])

100*sum([INTER_ENB_S1_HO_SUCC]) /sum([INTER_ENB_S1_HO_PREP])

100*sum([M8016C12]) / sum([M8016C11])

100*sum([M8016C11] - [M8016C12]) / sum([M8016C11])

100*sum([M8016C13]) / sum([M8016C11])

100*sum([M8021C2]) / sum([M8021C0])

100*sum([M8021C3]) / sum([M8021C1])

avg([M8012C26]) avg([PDCP_DATA_RATE_MEAN_DL])

avg([M8012C143]) avg([PDCP_DATA_RATE_MEAN_DL_QCI_1])

avg([M8012C23]) avg([PDCP_DATA_RATE_MEAN_UL])

avg([M8012C116]) avg([PDCP_DATA_RATE_MEAN_UL_QCI_1])

avg([M8011C37])/10 avg([DL_PRB_UTIL_TTI_MEAN])/10

avg([M8011C24])/10 avg([UL_PRB_UTIL_TTI_MEAN])/10

sum([M8020C3]) / sum([M8020C6])*100%

sum([M8020C4]) / sum([M8020C6])*100%

100*sum([CSFB_REDIR_CR_CMODE_ATT]) /sum([CSFB_REDIR_CR_ATT])

100*sum([CSFB_REDIR_CR_ATT] -[CSFB_REDIR_CR_CMODE_ATT]) /sum([CSFB_REDIR_CR_ATT])

100*sum([CSFB_REDIR_CR_EMERGENCY_ATT]) /sum([CSFB_REDIR_CR_ATT])

100*sum(HO_INTFREQ_SUCC]) /sum (HO_INTFREQ_ATT])

100*sum(HO_INTFREQ_GAP_SUCC]) /sum (HO_INTFREQ_GAP_ATT])

sum([M8012C18])*8 /(sum(MEASUREMENT_DURATION)*60)

sum([RLC_PDU_VOL_TRANSMITTED])*8 /(sum(MEASUREMENT_DURATION)*60)


sum([RLC_PDU_VOL_RECEIVED])*8 /(sum(MEASUREMENT_DURATION)*60)


sum([VOLUME_X2_IN_SIG_DATA])*8 /(sum(MEASUREMENT_DURATION)*60)


sum([VOLUME_X2_OUT_SIG_DATA])*8 /(sum(MEASUREMENT_DURATION)*60)

sum([M8004C2])*8/1000/(sum(MEASUREMENT_DURATION)*60)

sum([X2_DATA_VOL_IN_UPLANE])*8/1000 /(sum(MEASUREMENT_DURATION)*60)

sum([M8004C3])*8/1000 /(sum(MEASUREMENT_DURATION)*60)

sum([X2_DATA_VOL_OUT_UPLANE])*8/1000 /(sum(MEASUREMENT_DURATION)*60)

sum([SAMPLES_CELL_AVAIL]) /sum([DENOM_CELL_AVAIL])*100%

sum([SAMPLES_CELL_PLAN_UNAVAIL]) /sum([DENOM_CELL_AVAIL])*100%

sum([M8020C5]) / sum([M8020C6])*100%

100*sum([M8020C3]/sum([M8020C6] - [M8020C4])

avg([M8001C147]) avg([DL_UE_DATA_BUFF_AVG])

avg([M8001C227]) avg([UE_DRB_DL_DATA_QCI_1])

avg([M8001C235]) avg([UE_DRB_DL_DATA_NON_GBR])

avg([M8001C150]) avg([UL_UE_DATA_BUFF_AVG])

avg([M8001C419]) avg([UE_DRB_UL_DATA_QCI_1])

avg([M8001C420]) avg([UE_DRB_UL_DATA_NON_GBR])

max([M8001C148]) max([DL_UE_DATA_BUFF_MAX])

max([M8001C151]) max([UL_UE_DATA_BUFF_MAX])

avg([M8018C0]) avg([ENB_LOAD_ACT_UE_AVG])

sum([ifInOctets15]) / 1000

sum([ifOutOctets15]) / 1000

sum([M51120C0]) / sum([M51120C4])*100%

FtpSessionTime[s] = t_sessionend-t_sessionstart

sum([SAMPLES_CELL_UNPLAN_UNAVAIL]) /sum([DENOM_CELL_AVAIL])*100%

100*sum(SAMPLES_CELL_AVAIL/sum(DENOM_CELL_AVAIL-SAMPLES_CELL_PLAN_UNAVAIL)

LTE_5073a =sum([M51120C1]) / 1000LTE_5662a =sum([M51127C1]) / 1000

LTE_5072b =sum([M51120C3]) / 1000LTE_5663b =sum([M51127C3]) / 1000

LTE_5075a = sum([M51120C1]) *8 /(sum(MEASUREMENT_DURATION)*60)LTE_5665a = sum([(M51127C1]) *8 /(sum(MEASUREMENT_DURATION)*60)

LTE_5075a = sum([ifInOctets15]) *8 /(sum(MEASUREMENT_DURATION)*60)LTE_5665a = sum([ifInOctets15]) *8 /(sum(MEASUREMENT_DURATION)*60)

LTE_5074b = sum([M51120C3]) *8/(sum(MEASUREMENT_DURATION)*60)LTE_5664b = sum([M51127C3]) *8/(sum(MEASUREMENT_DURATION)*60)

LTE_5074b = sum([ifOutOctets15]) *8 /(sum(MEASUREMENT_DURATION)*60)LTE_5664b = sum([ifOutOctets15]) *8 /(sum(MEASUREMENT_DURATION)*60)

sum([ifInErrors15]) /sum([ifInPackets15])*100%

FtpCmdSR= number_of(successful_ftp_commands\number_of(total_ftp_commands)*100

FtpSessionSR=number_of(completed_sessions)\number_of(sucessfully_started_sessions)*100

FtpServiceAccessTime[s]=t_content sent or received-t_ftp command started

Attach Time [ms] = tAttach Complete – tAttach Request

FtpMeanDataRateUL/DL = {transffered_data_volume_UL/DL[bytes]*8}\{transfer_time[s]}

VoIPCallSetupTime [s] = t Connection Established − t Push Dial Button

VoIPCallSR ={ number_of (successful_calls)}\{number_of (call_setup_requests)}*100



VoIPFER = {number_of (lost_corrupted_discarded_frames)}\{number_of (all_frames_sent)}*100

Voice Interrupt Time [ms] = tfirst packet TeNB – tlast packet SeNB

LTENwAttSR = (number_of_successful_attachments)\(number_of_all_attempts)*100%

Service Request Time [ms] = tRRC_Reconfig – tRRC_Request

Service Request Time [s] = tRRC_Reconfig – tRRC_Request

EPSSR =[number_of(RRC_CONN_RECONFIGURATION_COMPLETE)]\[number_of(RRC_CONNECTION_REQUEST)]*100

EPSBearerD R = [number_of(dropped_calls)]\[number_of(successful_calls)]*100

Handover Procedure Time [ms] = tHO_Confirm – tHO_Command

HOSR = [number_of(Handover_Confirm)]\[number_of(Handover_Request)]*100

Paging Time [s] = tSRT network = initiated – tSRT UE initiated

PagingFR = [number_of(Paging_Failures)]\[number_of(Paging_Attempts)]*100

Rate={100}*[L.Paging.UU.Succ]/[L.Paging.UU.Att]

Round Trip Time [ms] = tICMP = Echo Reply – tICMP Echo Request

UserDataRate = (transferred_data_volume[bytes]*8\(transfer_time[s])*1000

PLR = [number_of(lost_corrupted_packets)]\[number_of(all_packets_sent)]*100

Service Interrupt Time [ms] = tfirst = packet to/from TeNB – tlast packet to/from SeNB

RBPLR = [number_of(lost_corrupted_packets)]\[number_of(all_packet_sent)]*100

RBUserDataRate = (transferred_data_volume [bytes])*8\(transfer_time [s])* 10–6

CellThroughput = (transferred_data_volume [bytes])*8\(transfer_time [s])* 10–6

Residual BLER = (number_of_lost_corrupted_radio_blocks)\(number_of_all_radio_blocks_sent)*100

rate=100*S1_mode_TAU_success_times/S1_mode_TAU_times

100* SAE_bearer_setup_success_times/ SAE_bearer_setup_request_times

Remarks

• intra LTE intra- and inter-frequency mobility• inter RAT mobility (LTE ↔ 2G/3G)• intra vs. inter eNB, the latter via X2, or S1 interface• intra vs. inter MME/S-GW

LTE_KPI_V1

Documents

Transcript of LTE_KPI_V1