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Telecom knowledge and experience sharing: LTE Drive Test Parameters
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LTE Drive Test Parameters Some important indicator LTE drive test parameters: 1. RSRP : Reference Signal Received Power. 2. RSRQ : Reference Signal Received Quality. 3. RSSI : Received Signal Strength Indicator. 4. SINR : Signal to Interference Noise Ratio. 5. CQI : Channel Quality Index. 6. PCI : Physical Cell Identity. 7. BLER: Block Error Ratio. 8. DL Throughput : Down Link Throughput. 9. UL Throughput : Up Link Throughput This is the common key performance parameters for LTE drive test parameter we have to work out for LTE drive test task.
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1. RSRP: RSRP – The average power received from a single Reference signal, and Its typical range is around 44dbm (good) to 140dbm(bad).
RSRP (dBm) = RSSI (dBm) – 10*log (12*N)
Telecom Knowledge Share 5G – waveform candidates by ROHDE&SCHW Apr 4, 2016 5:43 PM 5G – limitations of LTE Apr 4, 2016 3:17 AM What is 5G by Rohde and Schwarz Apr 28, 2016 2:46 AM Indoor Digitalization Solution Jul 26, 2016 7:31 AM LTE FDD APT700 by Huawei Sep 1, 2016 2:44 AM Tower Climber RSS Feed Widget
2. RSRQ: RSRQ – Indicates quality of the received signal, and its range is typically 19.5dB(bad) to 3dB (good).
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Reference Signal Received Quality (RSRQ) is defined as the ratio N×RSRP/(EUTRA carrier RSSI), where N is the number of RB’s of the EUTRA carrier RSSI measurement bandwidth. The measurements in the numerator and denominator shall be made over the same set of resource blocks.
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3. RSSI: RSSI – Represents the entire received power including the wanted power from the serving cell as well as all co channel power and other sources of noise and it is related to the above parameters through the following formula:
RSRQ=N*(RSRP/RSSI) Where N is the number of Resource Blocks of the EUTRA carrier RSSI measurement bandwidth. RSSI (Received Signal Strength Indicator) is a parameter which provides information about total received wide band power (measure in all symbols) including all interference and thermal noise. RSSI is not reported to eNodeB by UE. It can simply be computed from RSRQ and RSRP that are, instead, reported by UE. RSSI = wideband power = noise + serving cell power + interference power So, without noise and interference, we have that 100% DL PRB activity: RSSI=12*N*RSRP
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Where: RSRP is the received power of 1 RE (3GPP definition) average of power levels received across all Reference Signal symbols within the considered measurement frequency bandwidth RSSI is measured over the entire bandwidth N, number of RBs across the RSSI, is measured and depends on the BW
4. SINR: SINR is the reference value used in the system simulation and can be defined: Wide band SINR SINR for a specific subcarriers (or for a specific resource elements) All measured over the same bandwidth!
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RSSP vs RSRQ vs RSSI vs SINR Below is a chart that shows what values are considered good and bad for the LTE signal strength values:
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Photo Galleries Planning Reference Signals recap: OFDMA Channel Estimation In simple the Reference Signal (RS) is mapped to Resource Elements (RE). This mapping follows a specific pattern (see to below). So at any point in time the UE will measure all the REs that carry the RS and average the measurements to obtain an RSRP reading.
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Channel estimation in LTE is based on reference signals (like ICH functionality in WCDMA) Reference signals position in time domain is fixed (0 and 4 for Type 1 Frame) whereas in frequency domain it depends on the Cell ID In case more than one antenna is used (e.g. MIMO) the Resource elements allocated to reference signals on one antenna are DTX on the other antennas Reference signals are modulated to identify the cell to which they belong
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Impact of serving cell power to RSRQ: Example for noise limited case (no interference): If all resource elements are active and are transmitted with equal power, then
RSRQ = N / 12N = 10.8 dB for 1Tx RSRQ = N / 20N = 13 dB for 2Tx taking DTX into (because RSRP is measured over 1 resource element and RSSI per resource block is measured over 12 resource elements).
that RSSI is only measured at those symbol times during which RS REs are transmitted – We do not have to take into the count DTx!!! So, when there is no traffic, and assuming only the reference symbols are transmitted (there are 2 of them within the same symbol of a resource block) from a single Tx antenna then the RSSI is generated by only the 2 reference symbols so the result becomes
RSRQ = N / 2N = 3 dB for 1Tx RSRQ = 6dB for 2Tx SNR vs. RSRP RSRP is measured for a single subcarrier, noisepower for 15KHz= 125.2dBm Noise figure = 7 dB Temperature = 290 K
Assumption: RSRP doesn’t contain noise power
Power Calculation Example Lets try to calculate RSRP, RSSI and RSRQ for one very simple case of one resource block with 12 sub carriers and 0.5 ms in time domain. Let’s assume the power of reference symbols (shown by red square) and power of other symbols carrying other data channels (shown by blue square) is same i.e. 0.021 watt Since RSRP is linear average of downlink reference signal for given channel bandwidth therefore
RSRP = 10*log (0.021*1000) = 13.2 dBm http://telecomknowledge.blogspot.in/2016/09/ltedrivetestparameters.html
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Telecom knowledge and experience sharing: LTE Drive Test Parameters While RSSI is total received wideband power. Therefore we have to add power of all 12 carriers in the given resource block
RSSI = 10*log(0.021*1000)+10*log(12) = 24 dBm RSRQ is now simple ratio of RSRP to RSSI with N=1
RSRQ = 10*log(0.021/(12*0.021)) = 10.79 dB
Understanding dBm vs dB dB is ratio between two power values while dBm is used to express an absolute value of power. So when we mention RSRP and RSSI we shall always use dBm since we are talking about absolute power values but we need to use dB with RSRQ since it is the ratio of RSRP to RSSI
5. CQI: The Channel Quality Indicator (CQI) contains information sent from a UE to the eNodeB to indicate a suitable downlink transmission data rate, i.e., a Modulation and Coding Scheme (MCS) value. CQI is a 4bit integer and is based on the observed signaltointerferenceplusnoise ratio (SINR) at the UE. The CQI estimation process takes into the UE capability such as the number of antennas and the type of receiver used for detection. This is important since for the same SINR value the MCS level that can be ed by a UE depends on these various UE capabilities, which needs to be taken into in order for the eNodeB to select an optimum MCS level for the transmission. The CQI reported values are used by the eNodeB for downlink scheduling and link adaptation, which are important features of LTE. In LTE, there are 15 different CQI values randing from 1 to 15 and mapping between CQI and modulcation scheme, transport block size is defined as follows (36.213)
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Telecom knowledge and experience sharing: LTE Drive Test Parameters
6. PCI: Cell ID sets the physical (PHY) layer Cell ID. This PHYlayer Cell ID determines the Cell ID Group and Cell ID Sector. There are 168 possible Cell ID groups and 3 possible Cell ID sectors; therefore, there are 3 * 168 = 504 possible PHYlayer cell IDs. When Cell ID is set to Auto, the demodulator will automatically detect the Cell ID. When Cell ID is set to Manual, the PHYlayer Cell ID must be specified for successful demodulation. The physical layer cell id can be calculated from the following formula:
PHYlayer Cell ID = 3*(Cell ID Group) + Cell ID Sector When Sync Type is set to CRS, the Cell ID Auto selection will be disabled, and Cell ID must be specified manually. This is because the demodulator needs to know the values of the CRS sequence to use for synchronization and because Cell ID determines these values. See RSPRS for more information.
7. BLER: 3GPP TS 34.121, F.6.1.1 defines block error ratio (BLER) as follows: "A Block Error Ratio is defined as the ratio of the number of erroneous blocks received to the total number of blocks sent. An erroneous block is defined as a Transport Block, the cyclic redundancy check (CRC) of which is wrong."
8/9. DL/UL Throughput: assume a 2×5 MHz LTE system. We first calculate the number of resource elements (RE) in a subframe (a subframe is 1 msec): 12 Subcarriers x 7 OFDMA Symbols x 25 Resource Blocks x 2 slots = 4,200 REs Then we calculate the data rate assuming 64 QAM with no coding (64QAM is the highest modulation for downlink LTE): 6 bits per 64QAM symbol x 4,200 Res / 1 msec = 25.2 Mbps The MIMO data rate is then 2 x 25.2 = 50.4 Mbps. We now have to subtract the overhead related to control signaling such as PDCCH and PBCH channels, reference & synchronization signals, and coding. These are estimated as follows: PDCCH channel can take 1 to 3 symbols out of 14 in a subframe. Assuming that on average it is 2.5 symbols, the amount of overhead due to PDCCH becomes 2.5/14 = 17.86 %. Downlink RS signal uses 4 symbols in every third subcarrier resulting in 16/336 = 4.76% overhead for 2×2 MIMO configuration The other channels (PSS, SSS, PBCH, PCFICH, PHICH) added together amount to ~2.6% of overhead The total approximate overhead for the 5 MHz channel is 17.86% + 4.76% + 2.6% = 25.22%. The peak data rate is then 0.75 x 50.4 Mbps = 37.8 Mbps. Note that the uplink would have lower throughput because the modulation scheme for most device classes is 16QAM in SISO mode only. There is another technique to calculate the peak capacity which I include here as well for a 2×20 MHz LTE system with 4×4 MIMO configuration and 64QAM code rate 1:
http://telecomknowledge.blogspot.in/2016/09/ltedrivetestparameters.html
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Telecom knowledge and experience sharing: LTE Drive Test Parameters Downlink data rate: Pilot overhead (4 Tx antennas) = 14.29% Common channel overhead (adequate to serve 1 UE/subframe) = 10% overhead = 6.66% Guard band overhead = 10% Downlink data rate = 4 x 6 bps/Hz x 20 MHz x (114.29%) x (110%) x (16.66%) x (110%) = 298 Mbps. Uplink data rate: 1 Tx antenna (no MIMO), 64 QAM code rate 1 (Note that typical UEs can only 16QAM) Pilot overhead = 14.3% Random access overhead = 0.625% overhead = 6.66% Guard band overhead = 10% Uplink data rate = 1 * 6 bps/Hz x 20 MHz x (114.29%) x (10.625%) x (16.66%) x (110%) = 82 Mbps. Alternative to these methods, one can refer to 3GPP document 36.213, Table 7.1.7.11, Table 7.1.7.2.11 and Table 7.1.7.2.21 for more accurate calculations of capacity. To conclude, the LTE capacity depends on the following: Channel bandwidth Network loading: number of subscribers in a cell which impacts the overhead The configuration & capability of the system: whether it’s 2×2 MIMO, SISO, and the MCS scheme.
Throughput Troubleshooting DL
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Telecom knowledge and experience sharing: LTE Drive Test Parameters
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Search ὐ
LTE Drive Test Parameters Some important indicator LTE drive test parameters: 1. RSRP : Reference Signal Received Power. 2. RSRQ : Reference Signal Received Quality. 3. RSSI : Received Signal Strength Indicator. 4. SINR : Signal to Interference Noise Ratio. 5. CQI : Channel Quality Index. 6. PCI : Physical Cell Identity. 7. BLER: Block Error Ratio. 8. DL Throughput : Down Link Throughput. 9. UL Throughput : Up Link Throughput This is the common key performance parameters for LTE drive test parameter we have to work out for LTE drive test task.
ὐ Search this Blog
1. RSRP: RSRP – The average power received from a single Reference signal, and Its typical range is around 44dbm (good) to 140dbm(bad).
RSRP (dBm) = RSSI (dBm) – 10*log (12*N)
Telecom Knowledge Share 5G – waveform candidates by ROHDE&SCHW Apr 4, 2016 5:43 PM 5G – limitations of LTE Apr 4, 2016 3:17 AM What is 5G by Rohde and Schwarz Apr 28, 2016 2:46 AM Indoor Digitalization Solution Jul 26, 2016 7:31 AM LTE FDD APT700 by Huawei Sep 1, 2016 2:44 AM Tower Climber RSS Feed Widget
2. RSRQ: RSRQ – Indicates quality of the received signal, and its range is typically 19.5dB(bad) to 3dB (good).
Others Learning Learning IP , WiMAX
Reference Signal Received Quality (RSRQ) is defined as the ratio N×RSRP/(EUTRA carrier RSSI), where N is the number of RB’s of the EUTRA carrier RSSI measurement bandwidth. The measurements in the numerator and denominator shall be made over the same set of resource blocks.
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3. RSSI: RSSI – Represents the entire received power including the wanted power from the serving cell as well as all co channel power and other sources of noise and it is related to the above parameters through the following formula:
RSRQ=N*(RSRP/RSSI) Where N is the number of Resource Blocks of the EUTRA carrier RSSI measurement bandwidth. RSSI (Received Signal Strength Indicator) is a parameter which provides information about total received wide band power (measure in all symbols) including all interference and thermal noise. RSSI is not reported to eNodeB by UE. It can simply be computed from RSRQ and RSRP that are, instead, reported by UE. RSSI = wideband power = noise + serving cell power + interference power So, without noise and interference, we have that 100% DL PRB activity: RSSI=12*N*RSRP
POPULAR ARTICLES
LTE Drive Test Parameter Some important indicator drive test parameters: RSRP : Reference Signal Received Power. Reference Signal Received Qual...
Telecom Industrial News Latest Telecom News: Operators, Vendors, Technologies RSS Feed Widget RSS Feed Widget
Where: RSRP is the received power of 1 RE (3GPP definition) average of power levels received across all Reference Signal symbols within the considered measurement frequency bandwidth RSSI is measured over the entire bandwidth N, number of RBs across the RSSI, is measured and depends on the BW
4. SINR: SINR is the reference value used in the system simulation and can be defined: Wide band SINR SINR for a specific subcarriers (or for a specific resource elements) All measured over the same bandwidth!
http://telecomknowledge.blogspot.in/2016/09/ltedrivetestparameters.html
Telecom News Android Ap Telecom news provides collection of latest telecommunication and wireless technology information, the latest news on telecommunications ind... Job Vacancy
1/8
9/13/2016
Telecom knowledge and experience sharing: LTE Drive Test Parameters
RSS Feed Widget Carrier from Cellular News Telecom Carrier from Cellu News ...
RSSP vs RSRQ vs RSSI vs SINR Below is a chart that shows what values are considered good and bad for the LTE signal strength values:
11 Useful Android Apps fo Telecommunication Engineers The useful of Android App which you might need and helps your work which related to techni departments, including BSS, NSS, Core MS,...
TAGS 5G Antenna Course DAS Drive Test ForumDiscussion GPRS GSM IMS
Q&A Job LTE LTE Document LTE Protocol Training LTEA Document MapInfo Modulation Optic Optimization Optimization3G Optimization4G
Photo Galleries Planning Reference Signals recap: OFDMA Channel Estimation In simple the Reference Signal (RS) is mapped to Resource Elements (RE). This mapping follows a specific pattern (see to below). So at any point in time the UE will measure all the REs that carry the RS and average the measurements to obtain an RSRP reading.
Webinar RF Signaling Site and Solu Spectrum Telco Magazine Telco Techno TelecomNews Tool Transmission Troubleshoo UMTS Training Useful Android App Engineering App Useful iOS App Video Tuto
WCDMA 3G
Channel estimation in LTE is based on reference signals (like ICH functionality in WCDMA) Reference signals position in time domain is fixed (0 and 4 for Type 1 Frame) whereas in frequency domain it depends on the Cell ID In case more than one antenna is used (e.g. MIMO) the Resource elements allocated to reference signals on one antenna are DTX on the other antennas Reference signals are modulated to identify the cell to which they belong
Telecom4G/LTE from Realwire
Cradlepoint Invests £4 million in New EMEA Headquarters in West Byfleet to Expansion Across Europe, Mid East and Africa 9/12/2016 IBC 2016: Skyworth Digital premieres world's firstever 4Genabled e reader 9/8/2016
HUBER+SUHNER debuts protection innovation for RF connector systems at CTIA Super Mobility 2016 9/7/2016
Quortus and Expeto cooperate to deliv advanced wireless networks 9/2/2016 HUBER+SUHNER to showcase latest technologies for buses at InnoTrans 2016 8/31/2016
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Telecom knowledge and experience sharing: LTE Drive Test Parameters
Impact of serving cell power to RSRQ: Example for noise limited case (no interference): If all resource elements are active and are transmitted with equal power, then
RSRQ = N / 12N = 10.8 dB for 1Tx RSRQ = N / 20N = 13 dB for 2Tx taking DTX into (because RSRP is measured over 1 resource element and RSSI per resource block is measured over 12 resource elements).
that RSSI is only measured at those symbol times during which RS REs are transmitted – We do not have to take into the count DTx!!! So, when there is no traffic, and assuming only the reference symbols are transmitted (there are 2 of them within the same symbol of a resource block) from a single Tx antenna then the RSSI is generated by only the 2 reference symbols so the result becomes
RSRQ = N / 2N = 3 dB for 1Tx RSRQ = 6dB for 2Tx SNR vs. RSRP RSRP is measured for a single subcarrier, noisepower for 15KHz= 125.2dBm Noise figure = 7 dB Temperature = 290 K
Assumption: RSRP doesn’t contain noise power
Power Calculation Example Lets try to calculate RSRP, RSSI and RSRQ for one very simple case of one resource block with 12 sub carriers and 0.5 ms in time domain. Let’s assume the power of reference symbols (shown by red square) and power of other symbols carrying other data channels (shown by blue square) is same i.e. 0.021 watt Since RSRP is linear average of downlink reference signal for given channel bandwidth therefore
RSRP = 10*log (0.021*1000) = 13.2 dBm http://telecomknowledge.blogspot.in/2016/09/ltedrivetestparameters.html
3/8
9/13/2016
Telecom knowledge and experience sharing: LTE Drive Test Parameters While RSSI is total received wideband power. Therefore we have to add power of all 12 carriers in the given resource block
RSSI = 10*log(0.021*1000)+10*log(12) = 24 dBm RSRQ is now simple ratio of RSRP to RSSI with N=1
RSRQ = 10*log(0.021/(12*0.021)) = 10.79 dB
Understanding dBm vs dB dB is ratio between two power values while dBm is used to express an absolute value of power. So when we mention RSRP and RSSI we shall always use dBm since we are talking about absolute power values but we need to use dB with RSRQ since it is the ratio of RSRP to RSSI
5. CQI: The Channel Quality Indicator (CQI) contains information sent from a UE to the eNodeB to indicate a suitable downlink transmission data rate, i.e., a Modulation and Coding Scheme (MCS) value. CQI is a 4bit integer and is based on the observed signaltointerferenceplusnoise ratio (SINR) at the UE. The CQI estimation process takes into the UE capability such as the number of antennas and the type of receiver used for detection. This is important since for the same SINR value the MCS level that can be ed by a UE depends on these various UE capabilities, which needs to be taken into in order for the eNodeB to select an optimum MCS level for the transmission. The CQI reported values are used by the eNodeB for downlink scheduling and link adaptation, which are important features of LTE. In LTE, there are 15 different CQI values randing from 1 to 15 and mapping between CQI and modulcation scheme, transport block size is defined as follows (36.213)
http://telecomknowledge.blogspot.in/2016/09/ltedrivetestparameters.html
4/8
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Telecom knowledge and experience sharing: LTE Drive Test Parameters
6. PCI: Cell ID sets the physical (PHY) layer Cell ID. This PHYlayer Cell ID determines the Cell ID Group and Cell ID Sector. There are 168 possible Cell ID groups and 3 possible Cell ID sectors; therefore, there are 3 * 168 = 504 possible PHYlayer cell IDs. When Cell ID is set to Auto, the demodulator will automatically detect the Cell ID. When Cell ID is set to Manual, the PHYlayer Cell ID must be specified for successful demodulation. The physical layer cell id can be calculated from the following formula:
PHYlayer Cell ID = 3*(Cell ID Group) + Cell ID Sector When Sync Type is set to CRS, the Cell ID Auto selection will be disabled, and Cell ID must be specified manually. This is because the demodulator needs to know the values of the CRS sequence to use for synchronization and because Cell ID determines these values. See RSPRS for more information.
7. BLER: 3GPP TS 34.121, F.6.1.1 defines block error ratio (BLER) as follows: "A Block Error Ratio is defined as the ratio of the number of erroneous blocks received to the total number of blocks sent. An erroneous block is defined as a Transport Block, the cyclic redundancy check (CRC) of which is wrong."
8/9. DL/UL Throughput: assume a 2×5 MHz LTE system. We first calculate the number of resource elements (RE) in a subframe (a subframe is 1 msec): 12 Subcarriers x 7 OFDMA Symbols x 25 Resource Blocks x 2 slots = 4,200 REs Then we calculate the data rate assuming 64 QAM with no coding (64QAM is the highest modulation for downlink LTE): 6 bits per 64QAM symbol x 4,200 Res / 1 msec = 25.2 Mbps The MIMO data rate is then 2 x 25.2 = 50.4 Mbps. We now have to subtract the overhead related to control signaling such as PDCCH and PBCH channels, reference & synchronization signals, and coding. These are estimated as follows: PDCCH channel can take 1 to 3 symbols out of 14 in a subframe. Assuming that on average it is 2.5 symbols, the amount of overhead due to PDCCH becomes 2.5/14 = 17.86 %. Downlink RS signal uses 4 symbols in every third subcarrier resulting in 16/336 = 4.76% overhead for 2×2 MIMO configuration The other channels (PSS, SSS, PBCH, PCFICH, PHICH) added together amount to ~2.6% of overhead The total approximate overhead for the 5 MHz channel is 17.86% + 4.76% + 2.6% = 25.22%. The peak data rate is then 0.75 x 50.4 Mbps = 37.8 Mbps. Note that the uplink would have lower throughput because the modulation scheme for most device classes is 16QAM in SISO mode only. There is another technique to calculate the peak capacity which I include here as well for a 2×20 MHz LTE system with 4×4 MIMO configuration and 64QAM code rate 1:
http://telecomknowledge.blogspot.in/2016/09/ltedrivetestparameters.html
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Telecom knowledge and experience sharing: LTE Drive Test Parameters Downlink data rate: Pilot overhead (4 Tx antennas) = 14.29% Common channel overhead (adequate to serve 1 UE/subframe) = 10% overhead = 6.66% Guard band overhead = 10% Downlink data rate = 4 x 6 bps/Hz x 20 MHz x (114.29%) x (110%) x (16.66%) x (110%) = 298 Mbps. Uplink data rate: 1 Tx antenna (no MIMO), 64 QAM code rate 1 (Note that typical UEs can only 16QAM) Pilot overhead = 14.3% Random access overhead = 0.625% overhead = 6.66% Guard band overhead = 10% Uplink data rate = 1 * 6 bps/Hz x 20 MHz x (114.29%) x (10.625%) x (16.66%) x (110%) = 82 Mbps. Alternative to these methods, one can refer to 3GPP document 36.213, Table 7.1.7.11, Table 7.1.7.2.11 and Table 7.1.7.2.21 for more accurate calculations of capacity. To conclude, the LTE capacity depends on the following: Channel bandwidth Network loading: number of subscribers in a cell which impacts the overhead The configuration & capability of the system: whether it’s 2×2 MIMO, SISO, and the MCS scheme.
Throughput Troubleshooting DL
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Telecom knowledge and experience sharing: LTE Drive Test Parameters
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