TR-398 Issue 2

WiFi Performance Test Plan

Mon May 16 15:00:30 PDT 2022

PDF Report

Test Setup Information
Device Under Test
Name adtran-root
SSIDs 
adtran-tr398 adtran-tr398
Passwords 
lanforge lanforge
BSSIDs 
e8:2c:6d:85:73:64 e8:2c:6d:85:73:6a
Notes [BLANK]
Estimated Run Time 24 m
Actual Run Time 29.812 m

Objective

The TR-398 Issue 2 WiFi Performance test plan by the Broadband forum provides a comprehensive set of tests to qualify the performance of WiFi access points (APs) designed for residential and small office environments. Radio performance, Throughput, Connection Stability, Airtime Fairness, AP Co-existence, Mu_MIMO Performance, Spatial Consistency and Long-term Stability are some of the test areas covered in this test plan. The test plan is designed for service providers deploying in home WiFi APs to qualify the APs in the lab before deployment and for equipment makers to test during the development of the APs. Candela Technologies offers a fully automated TR-398 Issue 2 test system. The user can select from the list of tests available. Most tests can run fully automated, though some require user interaction. Measurements are made and compared to the specified PASS/FAIL criteria in the TR-398 Issue 2 test plan and this report will show the summary PASS/FAIL results followed more detailed results for each test.


Summary Results

Test Result Candela
Score 		Elapsed Info
Issue-3 Latency Test 2.4Ghz FAIL
5Ghz FAIL 		309 29.62 m Total CX Passing Throughput: 192 / 198 96.97%
Total CX Passing 2.4 AX: 25.0 / 99.0 25.253%
Total CX Passing 5Ghz AX: 34.0 / 99.0 34.343%

Issue-3 Latency Test


Summary

The Latency test intends to verify latency under low, high, and maximum AP traffic load, with 1 and 32 stations. Traffic load is 4 bi-directional TCP streams for each station, plus a low speed UDP connection to probe latency.

Test Procedure

DUT should be configured for 20Mhz on 2.4Ghz and 80Mhz on 5Ghz and stations should use two spatial streams.
  1. For each combination of: 2.4Ghz N, 5Ghz AC, 2.4Ghz AX, 5Ghz AX:
  2. Configure attenuators to emulate 2-meter distance between stations and AP.
  3. Create 32 stations and allow one to associate with the DUT. The other 31 are admin-down.
  4. Create AP to Station (download) TCP stream, and run for 120 seconds, record throughput as 'maximum_load'. Stop this connection.
  5. Calculate offered_load as 1% of maximum_load.
  6. Create 4 TCP streams on each active station, each configured for Upload and Download rate of offered_load / (4 * active_station_count * 2).
  7. Create 1 UDP stream on each active station, configured for 56kbps traffic Upload and 56kbps traffic Download.
  9. Start all TCP and UDP connections. Wait 30 seconds to let traffic settle.
  10. Every 10 seconds for 120 seconds, record bi-directional latency over the last 10 seconds for each UDP connection. Depending on test equipment features, this may mean you need to start/stop the UDP every 10 seconds or clear the UDP connection counters.
  11. Calculate offered_load as 70% of maximum_load, and repeat steps 6 - 9 inclusive.
  12. Calculate offered_load as 125% of maximum_load, and repeat steps 6 - 9 inclusive.
  13. Allow the other 31 stations to associate, and repeat steps 5 - 11 inclusive with all 32 stations active.

Pass/Fail Criteria

  1. For each test configuration running at 1% of maximum load: Average of all UDP latency samples must be less than 15ms.
  2. For each test configuration running at 1% of maximum load: Maximum of all UDP latency samples must be less than 25ms.
  3. For each test configuration running at 70% of maximum load: Average of all UDP latency samples must be less than 25ms.
  4. For each test configuration running at 70% of maximum load: Maximum of all UDP latency samples must be less than 45ms.
  5. For each test configuration running at 125% of maximum load: Average of all UDP latency samples must be less than 55ms.
  6. For each test configuration running at 125% of maximum load: Maximum of all UDP latency samples must be less than 105ms.
  7. For each test configuration: Each UDP connection upload throughput must be at least 1/2 of requested UDP speed for final 10-second test interval.
  8. For each test configuration: Each UDP connection download throughput must be at least 1/2 of requested UDP speed for final 10-second test interval.

Candela Score

The Candela Score for Latency Test is calculated as:
  1. 50 multiplied by the ratio of average latency compared to the pass/fail threshold.
  2. 0.25 multiplied by the percentagee of individual UDP connections that passed the pass/fail latency threshold.
  3. 0.25 multiplied by the percentagee of individual UDP connections that passed the pass/fail throughput threshold.

Issue-3 Latency Test Results

Type Result Value P/F Value Notes
AX 2.4Ghz STA1 INFO Reported TCP throughput: 235.46 Mbps
AX 2.4Ghz Sta-Count 1 Speed 1% PASS 0.83 15.00 Average UDP DL Latency: 0.83
Amount Stations passing Latency: 1 / 1
Amount Stations passing Throughput: 1 / 1
Min Sample Latency: 0
Max Sample Latency: 5.00
AX 2.4Ghz Sta-Count 1 Speed 70% PASS 10.00 25.00 Average UDP DL Latency: 10.00
Amount Stations passing Latency: 1 / 1
Amount Stations passing Throughput: 1 / 1
Min Sample Latency: 9.00
Max Sample Latency: 11.00
AX 2.4Ghz Sta-Count 1 Speed 125% FAIL 69.50 55.00 Average UDP DL Latency: 69.50
Amount Stations passing Latency: 0 / 1
Amount Stations passing Throughput: 1 / 1
Min Sample Latency: 65.00
Max Sample Latency: 73.00
AX 2.4Ghz Sta-Count 32 Speed 1% PASS 1.49 25.00 Average UDP DL Latency: 1.49
Amount Stations passing Latency: 32 / 32
Amount Stations passing Throughput: 32 / 32
Min Sample Latency: 0
Max Sample Latency: 11.00
AX 2.4Ghz Sta-Count 32 Speed 70% FAIL 547.06 45.00 Average UDP DL Latency: 547.06
Amount Stations passing Latency: 0 / 32
Amount Stations passing Throughput: 31 / 32
Min Sample Latency: 116.00
Max Sample Latency: 1,931.00
AX 2.4Ghz Sta-Count 32 Speed 125% FAIL 575.79 105.00 Average UDP DL Latency: 575.79
Amount Stations passing Latency: 0 / 32
Amount Stations passing Throughput: 30 / 32
Min Sample Latency: 140.00
Max Sample Latency: 1,621.00
AX 5Ghz STA1 INFO Reported TCP throughput: 853.22 Mbps
AX 5Ghz Sta-Count 1 Speed 1% PASS 0.17 15.00 Average UDP DL Latency: 0.17
Amount Stations passing Latency: 1 / 1
Amount Stations passing Throughput: 1 / 1
Min Sample Latency: 0
Max Sample Latency: 1.00
AX 5Ghz Sta-Count 1 Speed 70% PASS 3.67 25.00 Average UDP DL Latency: 3.67
Amount Stations passing Latency: 1 / 1
Amount Stations passing Throughput: 1 / 1
Min Sample Latency: 3.00
Max Sample Latency: 4.00
AX 5Ghz Sta-Count 1 Speed 125% FAIL 54.50 55.00 Average UDP DL Latency: 54.50
Amount Stations passing Latency: 1 / 1
Amount Stations passing Throughput: 0 / 1
Min Sample Latency: 49.00
Max Sample Latency: 64.00
AX 5Ghz Sta-Count 32 Speed 1% FAIL 26.01 25.00 Average UDP DL Latency: 26.01
Amount Stations passing Latency: 21 / 32
Amount Stations passing Throughput: 32 / 32
Min Sample Latency: 13.00
Max Sample Latency: 93.00
AX 5Ghz Sta-Count 32 Speed 70% FAIL 471.40 45.00 Average UDP DL Latency: 471.40
Amount Stations passing Latency: 0 / 32
Amount Stations passing Throughput: 31 / 32
Min Sample Latency: 54.00
Max Sample Latency: 3,539.00
AX 5Ghz Sta-Count 32 Speed 125% FAIL 631.14 105.00 Average UDP DL Latency: 631.14
Amount Stations passing Latency: 1 / 32
Amount Stations passing Throughput: 31 / 32
Min Sample Latency: 78.00
Max Sample Latency: 4,579.00
Configuration NOTE INFO Configured to skip N/AC test.
Configuration NOTE INFO Configured to skip N/AC test.


AX 2.4Ghz UDP Two-Way Latency (ms) for single station.

CSV Data for AX 2.4Ghz UDP Two-Way Latency for single station
 AX 2.4Ghz UDP Two-Way Latency for single station

AX 2.4Ghz UDP Two-Way Latency (ms) for each station.

CSV Data for AX 2.4Ghz UDP Two-Way Latency for 32 stations
 AX 2.4Ghz UDP Two-Way Latency for 32 stations

AX 2.4Ghz UDP Throughput (kbps) for each station.

CSV Data for AX 2.4Ghz UDP Throughput for 1 station
 AX 2.4Ghz UDP Throughput for 1 station

AX 2.4Ghz UDP Throughput (kbps) for each station.

CSV Data for AX 2.4Ghz UDP Throughput for 32 stations
 AX 2.4Ghz UDP Throughput for 32 stations

Per-Protocol Latency Graph shows the average latency for the different protocol types created by this test. If opposite-direction traffic is selected, the the latency will be round-trip, otherwise it will just report one-way latency. TCP latency may be misleading because it the time taken for the entire 'pdu' to be transmitted. The PDU is often 64kb. UDP latency is per UDP frame.


UDP Latency Graph shows the average latency for the UDP traffic created by this test. If opposite-direction traffic is selected, the the latency will be round-trip, otherwise it will just report one-way latency.


Per-Protocol Latency Graph shows the average latency for the different protocol types created by this test. If opposite-direction traffic is selected, the the latency will be round-trip, otherwise it will just report one-way latency. TCP latency may be misleading because it the time taken for the entire 'pdu' to be transmitted. The PDU is often 64kb. UDP latency is per UDP frame.


UDP Latency Graph shows the average latency for the UDP traffic created by this test. If opposite-direction traffic is selected, the the latency will be round-trip, otherwise it will just report one-way latency.


Per-Protocol Latency Graph shows the average latency for the different protocol types created by this test. If opposite-direction traffic is selected, the the latency will be round-trip, otherwise it will just report one-way latency. TCP latency may be misleading because it the time taken for the entire 'pdu' to be transmitted. The PDU is often 64kb. UDP latency is per UDP frame.


UDP Latency Graph shows the average latency for the UDP traffic created by this test. If opposite-direction traffic is selected, the the latency will be round-trip, otherwise it will just report one-way latency.


Per-Protocol Latency Graph shows the average latency for the different protocol types created by this test. If opposite-direction traffic is selected, the the latency will be round-trip, otherwise it will just report one-way latency. TCP latency may be misleading because it the time taken for the entire 'pdu' to be transmitted. The PDU is often 64kb. UDP latency is per UDP frame.


UDP Latency Graph shows the average latency for the UDP traffic created by this test. If opposite-direction traffic is selected, the the latency will be round-trip, otherwise it will just report one-way latency.


Per-Protocol Latency Graph shows the average latency for the different protocol types created by this test. If opposite-direction traffic is selected, the the latency will be round-trip, otherwise it will just report one-way latency. TCP latency may be misleading because it the time taken for the entire 'pdu' to be transmitted. The PDU is often 64kb. UDP latency is per UDP frame.


UDP Latency Graph shows the average latency for the UDP traffic created by this test. If opposite-direction traffic is selected, the the latency will be round-trip, otherwise it will just report one-way latency.


Per-Protocol Latency Graph shows the average latency for the different protocol types created by this test. If opposite-direction traffic is selected, the the latency will be round-trip, otherwise it will just report one-way latency. TCP latency may be misleading because it the time taken for the entire 'pdu' to be transmitted. The PDU is often 64kb. UDP latency is per UDP frame.


UDP Latency Graph shows the average latency for the UDP traffic created by this test. If opposite-direction traffic is selected, the the latency will be round-trip, otherwise it will just report one-way latency.


AX 5Ghz UDP Two-Way Latency (ms) for single station.

CSV Data for AX 5Ghz UDP Two-Way Latency for single station
 AX 5Ghz UDP Two-Way Latency for single station

AX 5Ghz UDP Two-Way Latency (ms) for each station.

CSV Data for AX 5Ghz UDP Two-Way Latency for 32 stations
 AX 5Ghz UDP Two-Way Latency for 32 stations

AX 5Ghz UDP Throughput (kbps) for each station.

CSV Data for AX 5Ghz UDP Throughput for 1 station
 AX 5Ghz UDP Throughput for 1 station

AX 5Ghz UDP Throughput (kbps) for each station.

CSV Data for AX 5Ghz UDP Throughput for 32 stations
 AX 5Ghz UDP Throughput for 32 stations

Per-Protocol Latency Graph shows the average latency for the different protocol types created by this test. If opposite-direction traffic is selected, the the latency will be round-trip, otherwise it will just report one-way latency. TCP latency may be misleading because it the time taken for the entire 'pdu' to be transmitted. The PDU is often 64kb. UDP latency is per UDP frame.


UDP Latency Graph shows the average latency for the UDP traffic created by this test. If opposite-direction traffic is selected, the the latency will be round-trip, otherwise it will just report one-way latency.


Per-Protocol Latency Graph shows the average latency for the different protocol types created by this test. If opposite-direction traffic is selected, the the latency will be round-trip, otherwise it will just report one-way latency. TCP latency may be misleading because it the time taken for the entire 'pdu' to be transmitted. The PDU is often 64kb. UDP latency is per UDP frame.


UDP Latency Graph shows the average latency for the UDP traffic created by this test. If opposite-direction traffic is selected, the the latency will be round-trip, otherwise it will just report one-way latency.


Per-Protocol Latency Graph shows the average latency for the different protocol types created by this test. If opposite-direction traffic is selected, the the latency will be round-trip, otherwise it will just report one-way latency. TCP latency may be misleading because it the time taken for the entire 'pdu' to be transmitted. The PDU is often 64kb. UDP latency is per UDP frame.


UDP Latency Graph shows the average latency for the UDP traffic created by this test. If opposite-direction traffic is selected, the the latency will be round-trip, otherwise it will just report one-way latency.


Per-Protocol Latency Graph shows the average latency for the different protocol types created by this test. If opposite-direction traffic is selected, the the latency will be round-trip, otherwise it will just report one-way latency. TCP latency may be misleading because it the time taken for the entire 'pdu' to be transmitted. The PDU is often 64kb. UDP latency is per UDP frame.


UDP Latency Graph shows the average latency for the UDP traffic created by this test. If opposite-direction traffic is selected, the the latency will be round-trip, otherwise it will just report one-way latency.


Per-Protocol Latency Graph shows the average latency for the different protocol types created by this test. If opposite-direction traffic is selected, the the latency will be round-trip, otherwise it will just report one-way latency. TCP latency may be misleading because it the time taken for the entire 'pdu' to be transmitted. The PDU is often 64kb. UDP latency is per UDP frame.


UDP Latency Graph shows the average latency for the UDP traffic created by this test. If opposite-direction traffic is selected, the the latency will be round-trip, otherwise it will just report one-way latency.


Per-Protocol Latency Graph shows the average latency for the different protocol types created by this test. If opposite-direction traffic is selected, the the latency will be round-trip, otherwise it will just report one-way latency. TCP latency may be misleading because it the time taken for the entire 'pdu' to be transmitted. The PDU is often 64kb. UDP latency is per UDP frame.


UDP Latency Graph shows the average latency for the UDP traffic created by this test. If opposite-direction traffic is selected, the the latency will be round-trip, otherwise it will just report one-way latency. 


Realtime Throughput for: Issue-3 Latency Test



Key Performance Indicators CSV


Test configuration and LANforge software version
Auto-Helper true
Use Issue-3 Behaviour true
Allow-11w (MFP/PMF) true
Skip 2.4Ghz Tests false
Skip 5Ghz Tests false
Duration-120 30
Duration-60 30
Channel 2Ghz 11
Channel 5Ghz 36
Extra Download Path-loss 0
TX Power 20
Multi-Conn 10
ToS 0
Upstream Port 1.2.eth2 Firmware: 0x80000aef, 1.1876.0 Resource: ct523c-3b89
Alien Upstream Port 1.2.2 eth2 Firmware: 0x80000aef, 1.1876.0 Resource: ct523c-3b89
Turn-Table Chamber TR-398
Configured 2m 2.4Ghz RSSI -26
Configured 2m 5Ghz RSSI -30
Opposite-Speed: 20000
Randomize Offered Load true
Allow Maximum NSS false
Max-CX Offered Load: 1000000
Max-CX 2Ghz N rate: 2000000
Max-CX 2Ghz AX rate: 3000000
Max-CX 5Ghz AC rate: 8000000
Max-CX 5Ghz AX rate: 10000000
Throughput N 2Ghz rate: 100000000
Throughput AC 5Ghz rate: 560000000
Throughput AX 2Ghz rate: 200000000
Throughput AX 5Ghz rate: 720000000
Skip 4x4 5Ghz test true
RvR issue 3 true
Throughput AX 2Ghz rate: 300000000
Throughput AX 2x2 5Ghz rate: 1100000000
Throughput AX 4x4 5Ghz rate: 1100000000
ATF Max NSS: 2
ATF Attenuation: 0
Allow Maximum NSS false
Max allowed packet loss%: 0.05
Assoc/Disassoc Traffic %: 99
Requested Rx-Sens Speed 65%
RxSens Rotation Degrees: 45
RxSens Start Step: 4
Attenuation Adjustment 0
Stop RX-Sens at pass false
Pause on zero throughput false
Spatial issue 3 true
Multiple STA issue 3 true
Use Virtual AX Stations false
Use AX Radios for AC tests true
Auto-Calibrate Interferer true
Use 40Mhz DUT to Avoid DFS false
Calibrate Alien with DUT Down false
LANforge-AP is Interferer true
Use AP-Coex Alien radios true
Use AP-Coex Alien Tx-Power true
User Interaction true
Interferer AC 5G-80Mhz: 195.00 Mbps
Interferer AC 5G-40Mhz: 90.00 Mbps
Interferer AC 2.4G-20Mhz: 32.00 Mbps
Interferer AX 5G-80Mhz: 195.00 Mbps
Interferer AX 5G-40Mhz: 90.00 Mbps
Interferer AX 2.4G-20Mhz: 32.00 Mbps
2Ghz Alien AP Radio: 1.4.3 wiphy0
5Ghz Alien AP Radio: 1.4.3 wiphy0
Alien AP TxPower: 0 dBm
2Ghz Alien STA Radio: 1.4.4 wiphy1
5Ghz Alien STA Radio: 1.4.4 wiphy1
Alien STA TxPower: 0 dBm
Spatial Rotation Degrees: 30
Test Retries: 0
Stability Duration-180 60
Stability Max-Iterations 5
Stability UDP Duration 5 m
Calibration Mode: 4
Calibration NSS: 1
LANforge AP Calibration Radio: 1.4.3 wiphy0
Mesh Node-1 LANforge AP Calibration Radio: 1.5.3 wiphy0
Calibrate against LANforge AP true
Background Scan Module simple
Background Short Interval 30
Background Long Interval 300
Background RSSI Threshold -65
WiFi Radio 0 1.1.5 wiphy1 Resource: ct523c-3b29
WiFi Radio 1 1.1.4 wiphy0 Resource: ct523c-3b29
WiFi Radio 2 1.1.7 wiphy3 Resource: ct523c-3b29
WiFi Radio 3 1.1.6 wiphy2 Resource: ct523c-3b29
WiFi Radio 4 1.1.9 wiphy5 Resource: ct523c-3b29
WiFi Radio 5 1.1.8 wiphy4 Resource: ct523c-3b29
WiFi AX Radio 0 1.2.wiphy0 Firmware: release/core68::058653f6 Resource: ct523c-3b89
WiFi AX Radio 1 1.2.wiphy1 Firmware: release/core68::058653f6 Resource: ct523c-3b89
WiFi AX Radio 2 1.2.wiphy2 Firmware: release/core68::058653f6 Resource: ct523c-3b89
WiFi AX Radio 3 1.2.wiphy3 Firmware: release/core68::058653f6 Resource: ct523c-3b89
WiFi AX Radio 4 1.2.wiphy4 Firmware: release/core68::058653f6 Resource: ct523c-3b89
WiFi AX Radio 5 1.2.wiphy5 Firmware: release/core68::058653f6 Resource: ct523c-3b89
WiFi AX Radio 6 1.2.wiphy6 Firmware: release/core68::058653f6 Resource: ct523c-3b89
WiFi AX Radio 7 1.2.wiphy7 Firmware: release/core68::058653f6 Resource: ct523c-3b89
WiFi AX Radio 8 1.2.wiphy8 Firmware: release/core68::058653f6 Resource: ct523c-3b89
WiFi AX Radio 9 1.2.wiphy9 Firmware: release/core68::058653f6 Resource: ct523c-3b89
WiFi AX Radio 10 1.2.wiphy10 Firmware: release/core68::058653f6 Resource: ct523c-3b89
WiFi AX Radio 11 1.2.wiphy11 Firmware: release/core68::058653f6 Resource: ct523c-3b89
WiFi AX Radio 12 1.3.wiphy0 Firmware: release/core68::058653f6 Resource: ct523c-de7c
WiFi AX Radio 13 1.3.wiphy5 Firmware: release/core68::058653f6 Resource: ct523c-de7c
WiFi AX Radio 14 1.3.wiphy10 Firmware: release/core68::058653f6 Resource: ct523c-de7c
WiFi AX Radio 15 1.3.wiphy15 Firmware: release/core68::058653f6 Resource: ct523c-de7c
WiFi AX Radio 16 1.3.wiphy1 Firmware: release/core68::058653f6 Resource: ct523c-de7c
WiFi AX Radio 17 1.3.wiphy6 Firmware: release/core68::058653f6 Resource: ct523c-de7c
WiFi AX Radio 18 1.3.wiphy11 Firmware: release/core68::058653f6 Resource: ct523c-de7c
WiFi AX Radio 19 1.3.wiphy16 Firmware: release/core68::058653f6 Resource: ct523c-de7c
WiFi AX Radio 20 1.3.wiphy2 Firmware: release/core68::058653f6 Resource: ct523c-de7c
WiFi AX Radio 21 1.3.wiphy7 Firmware: release/core68::058653f6 Resource: ct523c-de7c
WiFi AX Radio 22 1.3.wiphy12 Firmware: release/core68::058653f6 Resource: ct523c-de7c
WiFi AX Radio 23 1.3.wiphy17 Firmware: release/core68::058653f6 Resource: ct523c-de7c
WiFi AX Radio 24 1.3.wiphy3 Firmware: release/core68::058653f6 Resource: ct523c-de7c
WiFi AX Radio 25 1.3.wiphy8 Firmware: release/core68::058653f6 Resource: ct523c-de7c
WiFi AX Radio 26 1.3.wiphy13 Firmware: release/core68::058653f6 Resource: ct523c-de7c
WiFi AX Radio 27 1.3.wiphy18 Firmware: release/core68::058653f6 Resource: ct523c-de7c
WiFi AX Radio 28 1.3.wiphy4 Firmware: release/core68::058653f6 Resource: ct523c-de7c
WiFi AX Radio 29 1.3.wiphy9 Firmware: release/core68::058653f6 Resource: ct523c-de7c
WiFi AX Radio 30 1.3.wiphy14 Firmware: release/core68::058653f6 Resource: ct523c-de7c
WiFi AX Radio 31 1.3.wiphy19 Firmware: release/core68::058653f6 Resource: ct523c-de7c
WiFi Mesh Radio 0 1.3.18 wiphy21 Firmware: release/core68::058653f6 Resource: ct523c-de7c
WiFi Mesh Radio 1 1.3.18 wiphy21 Firmware: release/core68::058653f6 Resource: ct523c-de7c
Attenuator 0 rssi-0-2.4Ghz: -22 rssi-0-5Ghz: -41 atten: 1.1.3094.0
Attenuator 1 rssi-0-2.4Ghz: -22 rssi-0-5Ghz: -41 atten: 1.1.3094.1
Attenuator 2 rssi-0-2.4Ghz: -22 rssi-0-5Ghz: -41 atten: 1.1.3094.2
Attenuator 3 rssi-0-2.4Ghz: -22 rssi-0-5Ghz: -41 atten: 1.1.3094.3
Attenuator 4 rssi-0-2.4Ghz: -27 rssi-0-5Ghz: -43 atten: 1.1.3102.0
Attenuator 5 rssi-0-2.4Ghz: -27 rssi-0-5Ghz: -43 atten: 1.1.3102.1
Attenuator 6 rssi-0-2.4Ghz: -27 rssi-0-5Ghz: -43 atten: 1.1.3099.0
Attenuator 7 rssi-0-2.4Ghz: -27 rssi-0-5Ghz: -43 atten: 1.1.3099.1
Attenuator 8 rssi-0-2.4Ghz: -25 rssi-0-5Ghz: -43 atten: 1.1.3102.2
Attenuator 9 rssi-0-2.4Ghz: -25 rssi-0-5Ghz: -43 atten: 1.1.3102.3
Attenuator 10 rssi-0-2.4Ghz: -25 rssi-0-5Ghz: -43 atten:
Attenuator 11 rssi-0-2.4Ghz: -25 rssi-0-5Ghz: -43 atten:
AX Attenuator 0 AX rssi-0-2.4Ghz: -30 rssi-0-5Ghz: -47 atten: 1.1.3100.3
AX Attenuator 1 AX rssi-0-2.4Ghz: -30 rssi-0-5Ghz: -47 atten: 1.1.3100.2
AX Attenuator 2 AX rssi-0-2.4Ghz: -30 rssi-0-5Ghz: -47 atten: NA
AX Attenuator 3 AX rssi-0-2.4Ghz: -30 rssi-0-5Ghz: -47 atten: NA
AX Attenuator 4 AX rssi-0-2.4Ghz: -36 rssi-0-5Ghz: -48 atten: 1.1.3100.1
AX Attenuator 5 AX rssi-0-2.4Ghz: -36 rssi-0-5Ghz: -48 atten: 1.1.3100.0
AX Attenuator 6 AX rssi-0-2.4Ghz: -36 rssi-0-5Ghz: -48 atten:
AX Attenuator 7 AX rssi-0-2.4Ghz: -36 rssi-0-5Ghz: -48 atten:
AX Attenuator 8 AX rssi-0-2.4Ghz: -50 rssi-0-5Ghz: -55 atten: 1.1.3099.3
AX Attenuator 9 AX rssi-0-2.4Ghz: -50 rssi-0-5Ghz: -55 atten: 1.1.3099.2
AX Attenuator 10 AX rssi-0-2.4Ghz: -50 rssi-0-5Ghz: -55 atten:
AX Attenuator 11 AX rssi-0-2.4Ghz: -50 rssi-0-5Ghz: -55 atten:
Mesh Attenuator 0 Mesh rssi-0-2.4Ghz: -39 rssi-0-5Ghz: -60 atten: 1.1.3249.0
Mesh Attenuator 1 Mesh rssi-0-2.4Ghz: -39 rssi-0-5Ghz: -60 atten: 1.1.3249.1
Mesh Attenuator 2 Mesh rssi-0-2.4Ghz: -39 rssi-0-5Ghz: -60 atten: 1.1.3249.2
Mesh Attenuator 3 Mesh rssi-0-2.4Ghz: -39 rssi-0-5Ghz: -60 atten: 1.1.3249.3
Mesh Attenuator 4 Mesh rssi-0-2.4Ghz: -41 rssi-0-5Ghz: -50 atten: 1.1.3232.0
Mesh Attenuator 5 Mesh rssi-0-2.4Ghz: -41 rssi-0-5Ghz: -50 atten: 1.1.3232.1
Mesh Attenuator 6 Mesh rssi-0-2.4Ghz: -41 rssi-0-5Ghz: -50 atten:
Mesh Attenuator 7 Mesh rssi-0-2.4Ghz: -41 rssi-0-5Ghz: -50 atten:
Mesh Attenuator 8 Mesh rssi-0-2.4Ghz: -30 rssi-0-5Ghz: -44 atten: 1.1.3232.2
Mesh Attenuator 9 Mesh rssi-0-2.4Ghz: -30 rssi-0-5Ghz: -44 atten: 1.1.3232.3
Mesh Attenuator 10 Mesh rssi-0-2.4Ghz: -30 rssi-0-5Ghz: -44 atten:
Mesh Attenuator 11 Mesh rssi-0-2.4Ghz: -30 rssi-0-5Ghz: -44 atten:
Show Events true
Build Date Fri May 13 12:37:20 PDT 2022
Git Version 76216a7f529f3f8aceeb3a610feb0f25374d7bd5


CSV Data

META Information for TR-398 Issue 2
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