networking:wireless_topic:wi-fi_6:wi-fi_6
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| networking:wireless_topic:wi-fi_6:wi-fi_6 [2024/06/18 14:00] – aperez | networking:wireless_topic:wi-fi_6:wi-fi_6 [2025/07/16 12:42] (current) – removed aperez | ||
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| - | **Wi-Fi Generations** | ||
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| - | * **Very High Throughput** (VHT) Multi-User Multiple Input Multiple Output (MU-MIMO) Communication in 802.11ac. | ||
| - | * **High Throughput Modulation and Coding Scheme** (HT-MCS), Used by 802.11n. Represented by an integer in the range of 0-76. | ||
| - | * **Very High Throughput Modulation and Coding Scheme** (VHT-MCS), Used by 802.11ac. Represented by an integer in the range of 0-9. | ||
| - | * **Modulation Scheme** Defines the phase and amplitude required for bit computing, from BPSK to QPSK to 16-QAM, 64-QAM, and 256-QAM. | ||
| - | * **Coding** Rate of bits transferred and Forward Error Correction. A 1/2 Coding means two bits are transferred, | ||
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| - | * **Data Width** Specifies the channel used: 20MHz, 40MHz, 80MHz, and 160MHz. | ||
| - | * **Guard Interval** Waiting time or pause between each packet transmission. 802.11n has 400ns, and 802.11ac has 800 ns. The smaller the guard interval, the faster the throughput. | ||
| - | * **Minimum SNR and RSSI** Determines the minimum SNR and RSSI required for a specific MSC index. | ||
| - | * **OFDMA is essentially a type of OFDM for multiple users**. It allocates in both the time domain and the frequency domain, allowing for multiple users—even those with widely varying use patterns or data loads. By comparison, OFDM can allocate only sequentially. | ||
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| - | **What are the key differences between OFDM and OFDMA for multiple access?** | ||
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| - | If you are interested in wireless communication technologies, | ||
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| - | **What is OFDM?** | ||
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| - | OFDM stands for orthogonal frequency division multiplexing. It is a technique that splits a high-bandwidth channel into many narrow-band subcarriers, | ||
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| - | **What is OFDMA?** | ||
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| - | OFDMA stands for orthogonal frequency division multiple access. It is an extension of OFDM that allows multiple users to share the same channel by assigning different subcarriers to different users. For example, user A may use subcarriers 1, 2, and 3, while user B may use subcarriers 4, 5, and 6. This way, OFDMA can support multiple access without causing collisions or wasting bandwidth. OFDMA also enables dynamic allocation of subcarriers based on the channel conditions and user demands, which can improve the performance and fairness of the network. | ||
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| - | **How do OFDM and OFDMA differ?** | ||
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| - | The main difference between OFDM and OFDMA is that OFDM is a single-user technique, while OFDMA is a multi-user technique. This means that OFDM can only transmit data from one transmitter to one receiver at a time, while OFDMA can transmit data from multiple transmitters to multiple receivers simultaneously. Another difference is that OFDM uses a fixed set of subcarriers for each transmission, | ||
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| - | **What are the advantages of OFDM and OFDMA?** | ||
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| - | OFDM and OFDMA have several advantages over other wireless communication techniques, such as the ability to achieve high data rates and spectral efficiency by using multiple subcarriers and modulation schemes, reduce inter-symbol interference and fading by using short symbols and guard intervals, simplify the receiver design by using FFT and IFFT operations to convert between the time and frequency domains, and support multiple antennas and spatial diversity by using MIMO and beamforming techniques. OFDMA specifically can support multiple access and increase the network capacity by allowing multiple users to share the same channel, improve the quality of service and user satisfaction by allocating subcarriers according to user needs and channel conditions, as well as reduce power consumption and interference by using subcarrier grouping and power control techniques. | ||
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| - | **What are the challenges of OFDM and OFDMA?** | ||
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| - | Despite their advantages, OFDM and OFDMA also face some challenges and limitations in wireless communication. These include sensitivity to frequency offset and phase noise, which can degrade the signal quality, as well as the need for accurate synchronization and channel estimation, which can increase the complexity and overhead of the transmission. Furthermore, | ||
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| - | **What are the applications of OFDM and OFDMA?** | ||
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| - | OFDM and OFDMA are widely used in various wireless communication standards and applications, | ||
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| - | **What is spatial streams in WiFi? | ||
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| - | Spatial multiplexing or space-division multiplexing (**SM, SDM or SMX**) is a multiplexing technique in MIMO wireless communication, | ||
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| - | **MIMO** technology involves the use of multiple antennas at both the transmitter and receiver to improve the throughput and reliability of wireless systems. Rather than relying on a single antenna to transmit and receive data, MIMO utilizes multiple antennas to simultaneously send and receive multiple data streams. | ||
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| - | **MU-MIMO** means Multi-User Multiple Input Multiple Output. It allows a signal AP to communicate with multiple devices simultaneously. **Unlike SU-MIMO**, it only enables multiple antennas to communicate with one device. | ||
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| - | Security for Public Networks: **WPA3** introduces the **Enhanced Open security mode**, which uses **Opportunistic Wireless Encryption (OWE)**. It provides encryption between the device and the access point, even in open Wi-Fi networks that do not require a password. WPA2 does not provide similar security for public networks. | ||
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| - | **WPA, short for __//WiFi Protected Access//__, is a WiFi security standard that is used to secure computer wireless networks. WPA2 (WiFi Protected Access 2) and WPA3 (WiFi Protected Access 3) are two advanced versions of WPA. They have some security improvements over WPA.** | ||
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| - | **WPA vs WPA2 vs WPA3 – Differences: | ||
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| - | '' | ||
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| - | **WPA2 is securer than WPA**, and is currently used by most WiFi networks. **WPA may be hackable** **while WPA2 and WPA3 is not**. WPA3 includes some important upgrades for wireless network security. WPA3 protect users’ passwords from brute-force attacks. It also adds much stronger 192-bit encryption to the standard to improve the security level a lot. If you emphasize much on WiFi network security, you should choose WPA3, at least WPA2. | ||
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| - | However, WPA3 and WPA2 requires **more processing power** than WPA to protect your WiFi network, so you need more powerful hardware. | ||
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| - | As for the **data encryption speed**, WPA vs WPA2 vs WPA3, **WPA3 is fastest while WPA is the slowest**. | ||
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| - | WPA3 is the successor to WPA2, and WPA2 replaces WPA. **WPA3 is the most advanced WiFi security standard among these three**. | ||
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| - | **WPA3 and WPA2 is not hackable theoretically**, | ||
| - | WPA3 includes more advanced encryption than WPA2 and WPA. **It is the safest.** | ||
| - | **WPA3/WPA2 requires more processing power than WPA.** | ||
| - | WPA3 and WPA2 support most new devices __but don’t support some old devices.__ | ||
| - | It’s advised to choose WPA3 since it’s faster and safer than its predecessors, | ||
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| - | {{pdfjs 46em >: | ||
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| - | ======WI-FI 6 REFERENCE====== | ||
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| - | **Spectral Mask:** | ||
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| - | **G**uard **I**nterval: | ||
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| - | Note: The data rate is approximate, | ||
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| - | **[[https:// | ||
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| - | **MCS TABLE (UPDATED WITH 802.11AX DATA RATES)** | ||
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| - | **802.11AX MCS TABLE (OFDM)** | ||
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| - | This table only presents the data rates for 802.11ax communications when OFDM is used: | ||
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| - | **Example: Aruba 650 Series Wi-Fi 6E APs** | ||
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| - | - **2.4GHz radio:** Four spatial streams MIMO for up to 1,147Mbps wireless data rate with HE40 802.11ax client devices (**__286.8 Mbps x 4 SS = 1,147.2 Mbps or aprox 1.1 Gbps__**). | ||
| - | - **5GHz radio:** Four spatial streams MIMO for up to 2.4Gbps wireless data rate with HE80 802.11ax client devices (**__600.5 Mbps x 4 SS = 2,402 Mbps or aprox 2.4 Gbps__**). | ||
| - | - **6GHz radio:** Four spatial streams MIMO for up to 4.8Gbps wireless data rate with HE160 802.11ax client devices (**//1,201 Mbps x 4 SS = 4,804 Mbps or aprox 4.8 Gbps//**). | ||
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| - | **Example: Cisco Catalyst 9136 / 9120 Series Access Points** | ||
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| - | Higher density modulation requires higher levels of signal strength, and wider channels require higher signal strength compared to narrower channels. As a result, the cell size for an AP that supports 256-QAM is much smaller than that of an AP that supports 64-QAM, as shown in this diagram. | ||
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| - | =====Reference Guide 802.11ax===== | ||
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| - | =====New Wireless LAN Technology: 802.11ax===== | ||
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| - | =====Wi-Fi 6 & For Dummies, Extreme Networks Special Edition===== | ||
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| - | **Example radio link calculation** | ||
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| - | **Design for Both Capacity and Coverage** | ||
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| - | **The Industrial, Scientific, and Medical (ISM)** frequency bands are designated radio frequency bands as defined by the ITU Radio Regulations. These frequency bands were set aside for RF use for purposes other than telecommunications. | ||
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| - | **U-NII: | ||
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| - | The Unlicensed National Information Infrastructure (**U-NII**) **radio band**, as defined by the United States Federal Communications Commission, is part of the radio frequency spectrum used by **WLAN devices** and by **many wireless ISPs**. | ||
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| - | As of March 2021, **U-NII** consists of **eight ranges**. **U-NII 1 through 4 are for 5 GHz WLAN (802.11a and newer), and 5 through 8 are for 6 GHz WLAN (802.11ax) use**. **U-NII 2 is further divided into three subsections.** | ||
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| - | **Wireless ISPs generally use 5.725–5.825 GHz.** | ||
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| - | In the USA licensed amateur radio operators are authorized 5.650–5.925 GHz by Part 97.303 of the FCC rules. | ||
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| - | //U-NII power limits are defined by the United States CFR Title 47 (Telecommunication), | ||
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| - | Many other countries use similar bands for Wireless communication due to a shared IEEE standard. However, regulatory use in individual countries may differ. | ||
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| - | The defunct European HiperLAN standard operates in same frequency band as the U-NII. | ||
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| - | **DFS:** is **dynamic frequency selection**, | ||
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| - | These channels specified by the **Wi-Fi Alliance** to be **__careful not to use frequencies that are already being used in multiple countries to prioritize military radars, satellite communication, | ||
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| - | Basically, under this standard, part of the **IEEE 802.11h**, it is contemplated that before selecting these channels, a scan will be done to see if there are no active radars in the area and communication will only be allowed to be established if the channel is free, otherwise the WiFi communication will dynamically move to any of the channels that are not part of this range. | ||
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| - | **The signal intensity on these channels is also regulated so as not to " | ||
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| - | **DFS channels of 1 and 10 minutes of listening and location of the signal from the** __**RADARS**__ On most Channels, **before starting to broadcast**, | ||
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| - | For this reason, **the channel availability verification process is legally required to avoid electromagnetic interference of the 5 GHz frequency with the RADAR**, **// | ||
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| - | The negative side of this is that, when weather RADARS that are close to Wi-Fi networks **launch a pulse**, the DFS security mechanism can cause users' **service to be interrupted for up to 10 minutes**. Not only this, but when a Router' | ||
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| - | **2.4 GHz has three non-overlapping channels** to work with, while **5 GHz has 24**. We don't always get to use all of the 5 GHz channels, but overall it offers a lot more space. | ||
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| - | The **5 GHz Wi-Fi** channel choices available in most home network equipment are selected to choose only non-overlapping channels. Choices vary by country, but in the United States, the most recommended non-overlapping **5 GHz** channels are **36**, **40**, **44**, **48**, **149**, **153**, **157**, and **161**. | ||
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| - | **Channel Planning** | ||
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| - | **2.4 GHz** | ||
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| - | To eliminate adjacent-channel (also called cross-channel) interference, | ||
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| - | **5 GHz** | ||
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| - | In the 5 GHz band, no 20 MHz channels partially overlap. In addition to this, there are 24 non-overlapping channels to work with, so making sure no same-channel cells touch is much easier. | ||
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| - | **Best practice:** | ||
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| - | **2.4 GHz (802.11b/ | ||
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| - | **Most countries** | ||
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| - | Graphical representation of Wireless LAN channels in 2.4 GHz band | ||
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| - | There are 14 channels designated in the 2.4 GHz range spaced 5 MHz apart (with the exception of a 12 MHz spacing before channel 14). | ||
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| - | Note that for 802.11g/n it is not possible to guarantee orthogonal frequency-division multiplexing (OFDM) operation thus affecting the number of possible non-overlapping channels depending on radio operation. | ||
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| - | Interference concerns | ||
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| - | As the protocol requires 16.25 to 22 MHz of channel separation (as shown above), adjacent channels overlap and will interfere with each other. Leaving 3 or 4 channels clear between used channels is recommended to avoid interference. The exact spacing required depends on the protocol and data rate selected as well as the electromagnetic environment where the equipment is used. | ||
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| - | When two or more 802.11b transmitters are operated in the same airspace, their signals must be attenuated by -50dBr and/or separated by 22 MHz to prevent interference. This is due to fact that the DSSS algorithm transmits data logarithmically along a 20 MHz bandwidth. The remaining 2 MHz gap is used as a guard band to allow sufficient attenuation along the edge channels. | ||
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| - | Note: The 40 MHz bands in the diagram above are labelled with their centre channel numbers, the management | ||
| - | interface of many Wi-Fi devices labels these bands with the centre channel of one of the 20 MHz bands they | ||
| - | overlap plus an Up or Down notation to specify the other half of the band i.e.: Channel 3 = Channel 1+Upper, or | ||
| - | Channel5+Lower and Channel 11 = Channel 9+Upper or Channel 13+Lower. | ||
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| - | **40 MHz Channel Plan** | ||
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| - | The diagram below is an example of a 40 MHz channel plan that does not use DFS channels. In the US, as well as in several other regions, there are only four non-overlapping 40 MHz channels available if DFS channels are not used. The example plan minimizes CCI because adjacent APs do not use the same frequencies. | ||
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| - | **80 MHz Channel Plan** | ||
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| - | This is an example of an 80 MHz channel plan that uses DFS channels. In the US, as well as in several other regions, there are six non-overlapping 80 MHz channels available if DFS channels are used. As with the 40 MHz plan, the example plan minimizes CCI because adjacent APs do not use the same frequencies. | ||
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| - | **Installation Examples** | ||
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| - | **Warehouse - example: | ||
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| - | __**Heights between 12 and 14 meters**__ | ||
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| - | **Physical installation**: | ||
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| - | **Antenna types and design** | ||
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| - | Excellent guide: | ||
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| - | **Wi-Fi mast tripod** | ||
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| - | **How often should an AP be placed for 5 Ghz:** | ||
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| - | - From the first AP, in a straight line, it would be about **21 meters**, which is approximately equivalent to about **-67dbm** (very good signal). | ||
| - | - The recommended overlap for the **2.4Ghz radio is 20%**. | ||
| - | - The standard value for the **5Ghz radio should be 15%**, which would be equal to **1.486 m.** | ||
| - | - This value would be multiplied by the distance, that is: __**21 m x 1.486 m = 31.206 m**__. | ||
| - | - Which means the next AP should be placed **31 meters from the first**. | ||
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| - | **Note: | ||
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| - | - **2.4 GHz bands** can reach up to** 46 meters indoors**, being **higher outdoors, since it reaches 92 meters**. | ||
| - | - **5 GHz bands will be less than 15 meters indoors and up to 30 meters outdoors**. | ||
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| - | ^ Fuerza | ||
| - | | -30 dBm | Increíble | ||
| - | | -67 dBm | Grandioso | ||
| - | | -70 dBm | Normal | ||
| - | | -80 dBm | Pobre | Intensidad mínima de la señal para la conectividad básica, como la conexión a la red. | ||
| - | | -90 dBm | Inutilizable | Intensidad de señal extremadamente baja que hace que cualquier funcionalidad, | ||
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| - | **[[https:// | ||
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| - | <WRAP center 100%> | ||
| - | ^Power (dBm)^Power (mW)^ | ||
| - | |-40 dBm|0.0001 mW| | ||
| - | |-30 dBm|0.001 mW| | ||
| - | |-20 dBm|0.01 mW| | ||
| - | |-10 dBm|0.1 mW| | ||
| - | |0 dBm|1 mW| | ||
| - | |1 dBm|1.2589 mW| | ||
| - | |2 dBm|1.5849 mW| | ||
| - | |3 dBm|1.9953 mW| | ||
| - | |4 dBm|2.5119 mW| | ||
| - | |5 dBm|3.1628 mW| | ||
| - | |6 dBm|3.9811 mW| | ||
| - | |7 dBm|5.0119 mW| | ||
| - | |8 dBm|6.3096 mW| | ||
| - | |9 dBm|7.9433 mW| | ||
| - | |10 dBm|10 mW| | ||
| - | |20 dBm|100 mW| | ||
| - | |30 dBm|1000 mW| | ||
| - | |40 dBm|10000 mW| | ||
| - | |50 dBm|100000 mW| | ||
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| - | **PoE** | ||
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| - | **WLAN Test** | ||
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| - | {{pdfjs 46em >: | ||
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| - | **What steps do you follow when troubleshooting a network issue?** | ||
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| - | - Clearly understand the user experience regarding support | ||
| - | - Separate the support metric between the Internet service and the WLAN connectivity by the user. | ||
| - | - Verification of the user's Wi-Fi card. | ||
| - | - Verification of the channel and connection frequency by the user and/or the WLAN system per AP, which is complying with the rules of non-overlapping and non-activation of the DFS UNII 2 ext channels. | ||
| - | - Comparative performance calculation, | ||
| - | - Analysis of materials that focus on absorption and dispersion of photons between wavelengths of 5 cm, 6 cm and 12.5 cm. | ||
| - | - Roaming analysis, power, sensors and channels. | ||
| - | - Verification of 802.1x/AAA service functionality; | ||
| - | - DNS, DHCP scope service, static ip, local firewall, local EDR, perimeter firewall rules, perimeter DPI, perimeter ACL/WCF, return routes on the side of the UTM or the operator' | ||
| - | - Verification of the configuration of the Ethernet ports of the AP or devices that intervene in the verification process, which comply with the minimum traffic rules (802.1Q/ | ||
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networking/wireless_topic/wi-fi_6/wi-fi_6.1718737205.txt.gz · Last modified: 2024/06/18 14:00 by aperez