WiFi Surveyor -- RF Spectrum Analyzer & 802.11 Network Software
WiFi Surveyor turns data collected from RF Explorer spectrum analyzers into graphical charts and displays in real time, enabling users to more readily visualize the RF environment, monitor RF signals, troubleshoot RF issues, and detect sources of RF interference. In addition to spectrum analysis, integrated in the application software is a full-featured, Wi-Fi scanner -- also known as an 802.11 network discovery tool. The software can be used to monitor wireless devices and RF interference that impact the performance, range and security of wireless networks. When installed on a laptop computer, WiFi Surveyor provides mobile, site survey information that facilitates optimal configuration of wireless networks and proper location of RF devices, and aids in identifying potential sources of interference.
NetSurveyor is a diagnostic tool that falls under the category of WiFi Scanners or 802.11 Network Discovery Tools. The best known in this category is NetStumbler. A discovery tool reports the Service Set Identifier (SSID) for each wireless network it detects, along with the channel used by the access point (AP) servicing that network. Dec 26, 2017 How to extend WiFi range as much as possible: find the optimal location for the range extender using Spot Finder Technology. If placed too far from an existing router, a wireless range extender may not expand WiFi or WiFi signal strength may be spotty. Spot Finder helps ensure your Linksys range extender is in the right spot.
Wifi Signal Strength. Well, you nowadays have WiFi analyzer apps, that do the bidding for you. These are the apps that lookout for any troubles regarding your WiFi signal strength. They even tend to go to the length of telling the techniques of banishing these very issues. Jan 10, 2018 The inSSIDer Wi-Fi scanner can do various tasks, including finding open Wi-Fi access points, tracking signal strength, saving logs with GPS records, collect data from wireless card and software, choose the best wireless channel available and more.
WiFi Surveyor offers a variety of diagnostic views of the data captured by the RF Explorer device. Employing multiple views of the data enhances your ability to gain a better understanding of the local, RF landscape in which your wireless network is operating. WiFi Surveyor includes two software modules integrated into one application — one for RF spectrum analysis and a second for performing 802.11 network discovery (i.e. Wi-Fi scanning). Armed with the information these tools provide allows you to make better decisions setting-up, configuring and maintaining your wireless network. Also, if a wireless network is performing poorly then WiFi Surveyor can aid in troubleshooting the problem and help you determine whether other wireless devices operating in the vicinity are the source of RF interference.
6G Combo, WiFi Combo
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NOTE: For evaluation purposes feel free to download the software applications. Without the RF Explorer device the software runs in a fully functional 'Demo mode' using simulated data.
In addition to running as a standalone, handheld device, RF Explorer can be connected to a PC where Windows software (e.g. Touchstone) is used to provide enhanced functionality and data analysis. The connection is made using a mini USB cable. (NOTE: A high quality USB cable should be used in order to limit EMC interference from the PC that could influence your measurements.)
WiFi Surveyor May Be Used For
- Optimally installing and maintaining wireless networks.
- Troubleshooting poor-performing wireless networks by detecting the presence of RF interference.
- As an aid in properly locating wireless devices so as to maximize range and throughput and minimize interference from competing wireless devices.
- As a learning tool to help understand the relationship between access points (BSSIDs), wireless networks (SSIDs), and Wi-Fi RF transmissions.
Documentation
Documentation for WiFi Surveyor can be found here.
Spectrum Trace View
Continuously scans and samples the signal strength (dBm) of RF transmissions within the specified frequency range.
Waterfall History
The 'Waterfall History' view is also known as a 'heatmap' graph. It provides a color-based visualization of the RF level and activity over time. As signal levels for specific frequencies or frequency ranges increase and decrease, the waterfall map varies its colors. This feature provides a quick glance back into the sweep history to identify aberrations or fluctuation in frequency levels.
Topographic Map
The 'Topographic Map' chart shows accumulated RF energy as a function of frequency. The power of the signal strength in dBm is shown across the frequency span. A signal strength with a relatively low occurrence is 'blueish' in color, whereas increasingly brighter colors are used for signal strengths that occur more frequently. Signal strengths that occur most often are 'redish' in color. Over time, this spectral view will approximate the steady-state RF energy signature of a given environment.
Delta Trace
Wifi Signal Strength Meter
The 'Delta Trace' view can be used to view small (or large) changes in the RF spectrum over time. Here's how it works... When scanning begins the first trace is saved as a 'snapshot'. For all subsequent scans, the snapshot trace is subtracted from the current trace and the difference, i.e. 'delta', is displayed. Plotting the data in this way makes it easy to detect RF changes that occurred since the initial 'snapshot'.
Threshold Trace
The 'Threshold Trace' view highlights with a yellow box those frequencies whose signal strength exceeds a user-defined threshold. This feature is especially useful for visually emphasizing strong signals (and deemphasizing weak ones), where the user gets to define 'strong' and 'weak' according to where they set the threshold..
Channel Heatmap (Channel-Centric)
A 'channel-centric' chart -- similar to the Waterfall History chart above -- the difference being that here we plot channels rather than frequencies.
Channel Spectrogram (Channel-Centric)
A 'channel-centric' chart -- displays a three-dimensional plot of channels as a function of time. Each channel is represented by its own set of bar graphs -- the Z-axis is time and the Y-axis is signal strength. As with the Channel Timecourse chart (below), this view makes it easy to visualize how RF interference affects different channels over time.
Channel Density (Channel-Centric)
A 'channel-centric' chart -- similar to the Topographic chart above -- the difference being that here we plot channels rather than frequencies. A signal strength that appears with a relatively low occurrence is 'blueish' in color, whereas increasingly brighter colors are used for signal strengths that occur more frequently. Signal strengths that occur most often are 'reddish' in color.
Channel Timecourse (Channel-Centric)
A 'channel-centric' chart -- useful for monitoring channels as a function of time. Each channel is represented by a different line -- the X-axis is time and the Y-axis is signal strength. In this way one can clearly follow how RF interference affects different Wi-Fi channels over time.
AP Grid View (Network Discovery)
This grid of local access points (APs) is updated in (semi) realtime.
AP Site Survey (Network Discovery)
Site survey of local access points (APs). The height of each elipse reflects the strength of an AP's beacon and NOT data throughput. The strength of an AP's beacon is an indication of how far away the AP is located from the point of measurement
AP Timecourse (Network Discovery)
Displays the beacon strength of each access point as a function of time.
AP Differential (Network Discovery)
Displays the current beacon strength of each access point compared with an earlier snapshot.
Occupied Channels (Network Discovery)
Combines the access points by channel and displays a summary of channel usage.
Channel Timecourse (Network Discovery)
Combines the access points by channel and displays a summary of channel usage as a function of time.
Channel Heatmap (Network Discovery)
Combines the access points by channel and displays a summary of channel usage as a Heatmap. The Heatmap chart is also known as a 'waterfall' graph. It is a 3-dimensional representation of the data, where the X-axis is the channel, the Y-axis is a time scale, and the 'Z-axis' is the beacon signal quality that uses a color scale.
Channel Spectrogram (Network Discovery)
A three-dimensional view of channel usage as a function of time. Each channel is represented by its own set of bar graphs -- the X-axis is the channel, the Z-axis is a time scale, and the Y-axis reports the signal strength of beacons as a signal quality (0 - 100%).
Data Logging
'Data Logging' mode allows recording of spectrum trace data (in CSV format) for extended periods. As the logging progresses it is displayed in the form of a waterfall / heatmap that gradually scrolls upward with each scan.
Included in the installation folder is an example of a VBA macro for viewing the CSV data as a heatmap in Microsoft Excel.
NOTE: The heatmap created above by Touchstone-Pro and the one below created by Excel use the same data but different color scales.
RF Explorer spectrum analyzer is a very unique device. When combined with WiFi Surveyor software you now have an RF diagnostic tool unmatched in price and performance. Armed with the ability to monitor RF signals, detect RF interference and view all RF activity that occurs in your environment, solving Wi-Fi problems just got a whole lot easier.
“What is a good signal level or signal-to-noise ratio (SNR) for Wi-Fi” is one of the most common questions in online forums. Typical answers are along the lines of “SNRs of 24-40 dB are considered good” but they do not explain the compromise in speeds you are potentially making due to the adaptive modulation and coding built into Wi-Fi technology. For the best Wi-Fi speeds, signal strengths of -50 dBm or greater or signal-to-noise ratios of 41 dB or greater are necessary. In a typical residential property, we show, using real-life measurements, that these targets are perfectly achievable, but generally only with multiple Wi-Fi Access Points rather than a single Wi-Fi router. Furthermore, the use of a single Wi-Fi router increases the chance of ‘not-spots’ – locations where absolutely no Wi-Fi service is possible. However, with modest planning and measurement, you can dramatically improve your Wi-Fi network and maximise speeds where you want them.
Don’t be fooled by Wi-Fi equipment manufacturers’ claims as the reality is Wi-Fi is often the weak link in the broadband chain
If you want a laugh, pop over and have a read of the websites of most Wi-Fi equipment manufacturers. With claims of massive speeds (such as 11,000 Mbps from the latest products), it’s no wonder that so many broadband users are disappointed when speed tests reveals speeds of only 1% or less of these claims. We cannot think of another area where performance claims exceed the reality experienced by broadband users by such an extent. The reality is that Wi-Fi speeds achieved in ideal radio conditions drop substantially in poorer conditions.
Up to now, the low broadband speeds achieved with basic broadband services have often masked poor Wi-Fi speeds. With a move now towards ultrafast broadband services, and with broadband usage expected to triple in the next five years, you need to ensure that your Wi-Fi network keeps ups. BT’s latest Full Fibre 1000 service offers download speeds up to 900 Mbps but a quick glance at Internet forums reveals many subscribers moaning that their own speed tests indicate real speeds much lower than this – due primarily to Wi-Fi. We believe that it’s pointless upgrading to ultrafast broadband services with very high speeds if your Wi-Fi network is not properly configured and optimised. Wi-Fi can only deliver the best speeds that it is capable of when the radio conditions are excellent, as described below. Fortunately, actions to dramatically improve your Wi-Fi speeds are straightforward.
Wifi Signal Strength Tester
Wi-Fi modulation and coding explained in a nutshell
Wi-Fi has been designed to cope with the challenges of radio wave propagation in typical buildings – where signal levels can rise and fall dramatically depending on your location with respect to your Wi-Fi router or Access Point. In general, signal levels fall as you move away from the Wi-Fi router or Access Point, and signals can be significantly attenuated as they travel through obstacles, such as walls, ceilings and doors.
One of the most important features of Wi-Fi is the system used for ‘coping’ with signal strength variability. The fundamental purpose of this is to maximise data rates wherever possible (when signal levels are excellent), while making Wi-Fi signals more robust (with slower data rates) when signal levels are poor to avoid data loss. This is called adaptive modulation and coding. Modulation and coding are different things but work together.
Modulation is concerned with how data/information is sent across the airwaves. Five modulation schemes can be used with 802.11ac Wi-Fi, depending on signal conditions. The most robust modulation scheme is called BPSK (or Binary Phase Shift Keying). QPSK (Quadrature Phase Shift Keying) doubles the data that can be sent in a certain time period but is more susceptible to noise and interference. Similarly, 16-QAM (Quadrature Amplitude Modulation) doubles the data rate of QPSK. 64-QAM and 256-QAM triple and quadruple the data rate of QPSK, respectively. Of all the modulation schemes available, 256-QAM can deliver the highest speeds, with eight times more data in a given time period than the most robust BPSK. However, it can only operate successfully when signal conditions are excellent.
Coding, or Forward Error Correction (FEC) coding to give its full name, is where extra bits of information are added to the Wi-Fi data transmitted to allow the transmitted data to be reconstituted if some of the data is lost due to noise or interference. The more bits of data that are added, the more robust the transmission becomes, and the more lost information can be reconstituted. However, adding more bits for coding means that fewer bits of useful information will be transmitted, reducing data rates. For Wi-Fi, the so-called FEC rate varies between 1/2 and 5/6. An FEC rate of 1/2 means that an extra bit of information is added for every bit sent to help correct for errors (which is the most robust), whereas an FEC rate of 5/6 means that an extra bit of information is only added for every six bits of information (which is the least robust).
Modulation and coding are used together, and the 802.11ac Wi-Fi standard defines ten possible modulation and coding combinations – which go from MCS0 (Modulation and Coding Scheme 0) through to MCS9, as shown in Table 1, below. MCS0 is the most robust combination in the presence of noise and interference but delivers the slowest speeds. It combines the most robust modulation (BPSK) with the most robust coding scheme. At the other extreme, MCS9 delivers the highest speeds but is the least robust against noise and interference as it combines the least robust modulation scheme (256-QAM) with the least robust coding scheme. MCS9 delivers 13.3 times the data rate of MCS0. The ability for Wi-Fi to adapt modulation and coding to suit radio conditions is what makes the system so powerful by maximising speeds where it can while also providing a base level of performance.
| Modulation and Coding Scheme | Modulation | FEC Coding Rate | Data rate (speed) |
|---|---|---|---|
| MCS0 (most robust) | BPSK | 1/2 | |
| MCS1 | QPSK | 1/2 | 2.0 times faster than MCS0 |
| MCS2 | QPSK | 3/4 | 3.0 times faster than MCS0 |
| MCS3 | 16-QAM | 1/2 | 4.0 times faster than MCS0 |
| MCS4 | 16-QAM | 3/4 | 6.0 times faster than MCS0 |
| MCS5 | 64-QAM | 2/3 | 8.0 times faster than MCS0 |
| MCS6 | 64-QAM | 3/4 | 9.0 times faster than MCS0 |
| MCS7 | 64-QAM | 5/6 | 10.0 times faster than MCS0 |
| MCS8 | 256-QAM | 3/4 | 12.0 times faster than MCS0 |
| MCS9 (least robust) | 256-QAM | 5/6 | 13.3 times faster than MCS0 |
Table 1: The ten possible modulation and coding schemes for 802.11ac Wi-Fi delivering very different speeds
Signal strength and signal-to-noise ratio explained in a nutshell
Before discussing recommended targets, it is important to explain and distinguish between the metrics that are commonly used and measured. Often the terms ‘signal strength’ and ‘signal-to-noise ratio’ are used in online forums to mean the same thing but they are different. If you want to properly set up and optimise your Wi-Fi network, we recommend that you use software designed to measure Wi-Fi networks. Our favourites are currently:
- NetSpot
- WiFi Explorer.
Both of these measure both signal strength and signal-to-noise ratio for all the Wi-Fi routers and Access Points in your vicinity. The screenshot shows measurements recorded using NetSpot. Your Wi-Fi network can be set up and optimised using either measure.
Figure 1: Screenshot of NetSpot showing signal strength and signal-to-noise ratio measurements
Signal strength is usually measured in dBm (which means the signal level compared to 1 mW measured on a dB scale). 0 dBm means 1 mW. -10 dBm means 0.1 mW and -20 dBm means -0.01 mW. Typically, measured signal levels are much lower than 1 mW so Wi-Fi signal strengths will be in negative numbers and will usually vary between -80 dBm (0.00000001 mW) and -30 dBm (0.001 mW). What may be confusing for some is that a smaller negative number is higher (better) than a large negative one. A signal strength of -50 dBm will only be achieved relatively close to the WiFi router or Access Point. Signal strengths of -75 dBm or lower are considered poor.
Signal-to-Noise Ratio (SNR) is the ratio (calculated in decibels) of the received signal strength to the noise level. To achieve a reliable connection, the signal level has to be significantly greater than the noise level. An SNR greater than 40 dB is considered excellent, whereas a SNR below 15 dB may result in a slow, unreliable connection.
Other factors affect Wi-Fi speeds
It is important to remember that Wi-Fi speeds and performance also depend on the Wi-Fi standard used, the frequency of operation and channel bandwidth used. We currently recommend:
- 802.11ac devices (in preference to newer, and more expensive 802.11ax devices)
- 5 GHz operation (in preference to 2.4 GHz)
- 80 MHz channel spacing (in preference to 40 MHz or 20 MHz).
Although early Wi-Fi routers and Access Points using the very latest Wi-Fi 6 802.11ax standard are now commercially available, measured speeds from early devices have been sporadic and performance is hampered by the lack of widespread availability of compatible devices. We, therefore, recommend using more tried-and-tested Wi-Fi 5 802.11ac devices currently.
5 GHz operation is strongly recommended over 2.4 GHz (which we actually turn off). There is, generally, less interference at 5 GHz, greater bandwidth and higher maximum speeds. While range at 2.4 GHz is generally less than 5 GHz, this can be offset through the use of multiple Wi-Fi Access Points.
Wider channel spacings at 5 GHz generally deliver higher speeds so, if you can, use 80 MHz channel spacing rather than 40 MHz or 20 MHz. While it is potentially possible to use an even wider 160 MHz channel spacing, not all devices support this and there may be insufficient bandwidth to operate multiple Wi-Fi Access Points (since different channels should be used on different Access Points to prevent interference).
A signal level of about -50 dBm or more is required to achieve maximum Wi-Fi speeds
Increasing signal level allows less robust modulation and coding schemes to be utilised, increasing Wi-Fi speeds, as shown in Figure 2 below. Results shown are for 802.11ac with 5 GHz operation and 80 MHz channel spacing. While a signal level of -76 dBm is sufficient for the most robust MCS 0 modulation-coding combination, Wi-Fi speed is only 7.5% of the maximum speed achievable. However, the ‘full-speed’ mode – which uses the least robust (MCS9) modulation-coding combination – is only possible with a signal level of about -50 dBm or more. In between these signal level extremes, different modulation-coding schemes will typically be employed. A signal level of at least -56 dBm is needed to keep speeds at least 75% of the maximum possible.
In a typical home, a single Wi-Fi router or Access Point will deliver a broad range of signal strengths at different locations, possibly forcing hard decisions to be made. Giving preference to a particular location (e.g. a particular living room chair) – to maximise speeds in that location – may mean much slower speeds elsewhere, as described below.
A signal-to-noise ratio of about 41 dB or more is required to achieve maximum Wi-Fi speeds
As with increasing signal level, increasing signal-to-noise ratio allows less robust and faster modulation/coding combinations to be used, as shown in Figure 3, below. As above, results shown are for 802.11ac with 5 GHz operation and 80 MHz channel spacing. While a signal-to-noise ratio of about 16 dB is sufficient to achieve a speed equivalent to only 7.5% of the maximum possible speed, the signal-to-noise ratio would need to be about 41 dB or more to achieve maximum speed.
Figure 3: Chart of Wi-Fi speed against signal-to-noise ratio [Source: Increase Broadband Speed]
Figure 3, above, shows why statements such as “SNRs of 24-40 dB are considered good” are so misleading. That is a wide SNR range, where the minimum level of 24 dB will only achieve a speed of about one-third of the maximum speed possible.
What this means in practice and the importance of optimally-placed, multiple Access Points
To help understand what these targets mean in practical terms, we want to share with you some real measurements made in a family house in the UK. The table below shows the measured signal-to-noise ratio (SNR) using the NetSpot application. Before measurements were performed, ten target locations were identified where residents expected to spend significant time and wanted to have excellent broadband service. Four Wi-Fi Access Points were used in order to provide excellent coverage to all the targeted locations, and signal-to-noise measurements for all locations (and to all Access Points) are shown in Table 2, below. Numbers shown in bold indicate when measurements exceed the minimum 41 dB SNR required to maximise Wi-Fi speeds (discussed previously).
| Target Location | Access Point 1 | Access Point 2 | Access Point 3 | Access Point 4 |
|---|---|---|---|---|
| Study desk | 47 dB | 44 dB | 24 dB | 15 dB |
| Lounge settee | 50 dB | 37 dB | 14 dB | 16 dB |
| Kitchen island | 30 dB | 18 dB | 17 dB | 48 dB |
| Dining room table | 31 dB | 13 dB | 52 dB | 11 dB |
| Games room settee | 25 dB | 44 dB | 30 dB | 47 dB |
| Main bedroom (bed) | 30 dB | 56 dB | 31 dB | 26 dB |
| Kid's bedroom 1 (desk) | 26 dB | 33 dB | 50 dB | 28 dB |
| Kid's bedroom 1 (bed) | 17 dB | 29 dB | 53 dB | 21 dB |
| Kid's bedroom 2 (desk) | 37 dB | 58 dB | 36 dB | 25 dB |
| Kid's bedroom 2 (bed) | 39 dB | 48 dB | 35 dB | 25 dB |
Table 2: Signal-to-noise ratio (SNR) measurements made in a family home in the UK
Even the best-placed Access Point (Access Point 2) was only able to deliver the target SNR (i.e. best speeds) to half of the targeted locations. Results for the other Access Points show that this proportion is substantially reduced if the location of a single Access Point is sub-optimal. While every Access Point was able to provide excellent SNRs to certain locations, they all left other targeted locations with poor or no service.
Four Access Points were necessary in this case to deliver the target SNR to all targeted locations. Using four Access Point, all ten target locations were able to achieve a minimum signal-to-noise ratio of 47 dB, with a mean signal-to-noise ratio across all ten locations of 51 dB. With the equipment we used, average throughputs of 650-720 Mbps were achieved (measured using iPerf3) at all locations using a range of devices (using 5 GHz and 80 MHz channel spacing). The achievement of higher throughputs would have required devices supporting 4 x 4 MIMO and/or 160 MHz channel bandwidths but the devices we used did not support either of these. Bear in mind that, with a Gigabit Ethernet connection to our Access Points, it would not be possible to exceed the throughput capabilities of Gigabit Ethernet.
Substantial compromises on the number of target locations and target SNR are inevitable with a reduced number of Access Points. Obviously, the exact compromises will depend on the size and geography of your house or office, which is why we recommend performing your own measurements. However, we feel our general results are representative of many UK households.
In conclusion, we feel there are two main approaches to setting signal strength or SNR targets:
- the targeted maximum-quality approach (which we recommend) where you aim to maximise Wi-Fi speeds at the locations that you use. Define a set of target locations and stringent targets (e.g. a minimum signal level of -50 dBm or minimum SNR of 41 dB) and optimise the placement of multiple Wi-Fi Access Points to achieve these target with the minimum number of Access Points possible.
- the performance compromise approach based on the number and location of Wi-Fi Access Points you are prepared to deploy. In general, reducing the number of Access Points and their location (ultimately to a single Wi-Fi router placed next to the BT master socket) may require significant compromise with target signal strength/SNR targets and the extent to which preferred locations can be covered.
Wifi Wireless Signal Strength Explorer
Only you can make this judgement. The targeted maximum-quality approach will ensure that your Wi-Fi network remains future-proof with the evolution towards ultrafast broadband services. If you are designing your Wi-Fi network to support an ultrafast broadband connection with speeds in excess of 200 Mbps, we strongly recommend minimum targets of -50 dBm (for signal strength) and/or 41 dB for SNR.
The performance compromise approach may result in substantial variations in Wi-Fi speeds and performance. Clearly, those with standard broadband connections or slow fibre broadband connections may be able to significantly relax requirements. However, our measurements show that, as the number of Access Points is reduced, the number of areas with poor performance increases. Any single Access Point will inevitably result in ‘not-spots’ i.e. locations where signal level or SNR are insufficient to sustain any service whatsoever, causing signal drop-outs or huge latency spikes (due to retransmissions).
Check Wifi Signal Strength
Despite the fact that you can substantially improve Wi-Fi performance, we strongly recommend that you use Ethernet cables to connect fixed devices (such as smart TVs and desktop PCs) rather than Wi-Fi if you can. As well as offering superior throughputs, latency is significantly lower too. This approach will also free up Wi-Fi capacity for your mobile devices. With our optimised Wi-Fi network, we were able to achieve average throughputs of 650-720 Mbps, with an average latency (ping) of about 4 ms. As a comparison, for client devices connected by Gigabit Ethernet rather than W-Fi, we were able to achieve an average throughput of 941 Mbps with average latency below 1 ms. Ethernet provides even better speeds with 10 Gigabit Ethernet (10 GbE). We have recently upgraded our network to 10 GbE and iPerf3 indicates an average throughput of 9.90 Gbps (using jumbo frames). Cables show no sign of giving way to wireless anytime soon!
Test Wifi Signal Strength
Other pages you may be interested in:
Wifi Signal Strength Windows 10
Best Wi-Fi Access Points For 2020 | Increase Broadband Speed Guide | Blog | Review of Ubiquiti’s UniFi Wi-Fi 6 Long Range Access Point | What Realistic Speed Will I Get With Wi-Fi 5 and Wi-Fi 6?