In the latest 5G Guys podcast episode, hosts Dan McVaugh and Wayne Smith interview Jeff Vaughn with Douglas County Sheriff’s Office and our very own Cody Martin on the important topic of public safety communication in schools.
They share common pitfalls as well as unexpected impact, and provide an overview of the work done by Castle Rock Microwave to enhance in-building communication.
From infrastructure to security, get 24/7 monitoring of your systems to ensure that when outages or issues occur, you’ll be able to react quickly with expert support.
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The City of Aurora is a Home Rule Municipality located in Arapahoe, Adams, and Douglas counties, Colorado. Aurora lies immediately east of Denver. It is one of the principal cities of the Denver–Aurora–Lakewood, CO Metropolitan Statistical Area and a major city of the Front Range Urban Corridor.
The City trusts Castle Rock Microwave to help them overcome their wireless connectivity challenges. As a result, they turned to CRM when they were looking to upgrade connectivity at several community locations in late 2020.
Castle Rock Microwave suggested wireless solutions from Cambium Networks in 60 and 80GHz. These millimeter wave frequencies are ideal for achieving fiber-like speeds at a fraction of the cost of building new fiber infrastructure.
We recommended the PTP850E for 80GHz and cnWave v5000 and v3000 for 60GHz. The PTP850E is an ultrahigh capacity, all-outdoor backhaul that delivers up to 20 Gbps capacity. The cnWave uses Terragraph, Facebook’s new terrestrial connectivity technology.
Terragraph opens up a new way to use the large amounts of unlicensed spectrum available in the 60 GHz millimeter Wave band, using a mesh architecture that can be used for many FWA, backhaul, smart cities and IoT use cases. With the increase in demand for gigabit connectivity and the availability of commercial equipment, Terragraph has become a hot technology, with the first large commercial deployments expected in 2021.
To find out more about Terragraph and the opportunities it offers to service providers, cities and enterprises, register here to receive the report that will be available soon, or download the interviews that will be part of the report as they become available.
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In 2020, rural telcos that provide wireless internet access have seen many rapidly developing events that have impacted their businesses. Instantaneous increases in demand due to COVID, RDOF applications, CBRS Auction and CARES Act money/grants have been pushing rural telcos to optimize network performance and capacity. In this article, I will address some of the performance issues rural telcos with broadband services are seeing and solutions to optimize wireless networks.
This increased demand has left many providers struggling to keep up to their overtaxed networks. In addition, they are having problems providing reliable service and their customers are starting to look for better alternatives.
In a recent article , Mike Dano states, “As office workers, students and others continue to seek shelter at home from COVID-19, demand for speedy and reliable Internet service appears to be at an all-time high. That demand is beginning to have serious effects on the nation’s telecommunications providers.” “Capgemini recently surveyed 6,300 US consumers and found that almost half (48%) felt their Internet connections didn’t meet their needs. The firm also found that customers are increasingly looking at their connection’s flexibility and network speeds, rather than just the reliability and price.”
With so much expansion occurring within internal networks and competitors’ networks, interference can slowly creep in degrading performance.
New users and greater capacity demands are now exposing issues with bandwidth management. Furthermore, poor bandwidth management from inefficient design practices decreases available bandwidth and decrease capacity in the distribution network.
There are solutions, but there are often tradeoffs as well. The decisions on performance are being driven by market demand and existing capacity. With rapid expansion of user expansion and bandwidth demand, your wireless access points and network can quickly become overburdened. Start with an audit of RF performance by an RF expert to see which problems you are experiencing.
One solution is using more directional antennas at access points. This will help performance by:
Another solution is using smaller cells or micro PoPs. This can increase capacity, improving the user experience. Each access point is limited the least common denominator of capacity its users are receiving. As a result, wide ranges of distances from the access points can play havoc on performance. Therefore, tighter variances and shorter distances will help set customer expectations.
Adding capacity is an obvious solution. 25/3 is no longer the real standard, users are now demanding 100’s of Megs or even Gigabit capacity. There is a new disruptive carrier class PTP option pushing multiple gigabits per second. And it is one of the most cost-effective solutions in terms of cost per megabit per second per mile. This product provides the highest capacity in a single transceiver radio with 2.5Gbps (single radio – 2x112MHz channels) or 1.5Gbps (single radio – 2x80MHx channels) at 4096 QAM. For more information on implementing this system, please visit our Case Study with South Park Telephone Company.
For the distribution network, implementing massive Multi-User MIMO or MU MIMO solutions will provide greater access to users and capacity. Many carriers are using less robust, standard MIMO solutions and are reaching user density thresholds. Accordingly, they need a technology leap to support more users at higher capacity. Cambium’s PMP450m (cnMedusa) is a high-capacity multi-point solution that can provide more than 400 Mbps actual usable throughput per sector, and communicate with up to seven Subscriber Modules simultaneously. With 8×8 MU MIMO it provides 4x more spectrum efficiency than any other vendor. It also impressive Near or Non-LOS capabilities as well for more flexible installations.
Purchasing microwave equipment is a long-term decision with implications on future needs, sustainability, and total cost of ownership. A few years ago, Brett Bonomo wrote an article on this topic that covers key questions to ask including:
For more detail visit the complete article at https://castlerockmicrowave.com/selecting-the-right-radio
Would you feel more comfortable hearing from others when evaluating technology? Great, there is a great Facebook page that hosts over 10,000 members where you will likely find answers to your many questions from companies much like yours.
CBRS (Citizens Broadband Radio Systems) is now being considered by many telcos for a last mile solution. If you are not familiar with this newly available spectrum (3550-3650MHz), here is a quick article on CBRS
What are some of the key advantages of CBRS?
With fewer issues of interference and more flexible antenna locations this means happier customers and fewer truck rolls to tweak your network.
Companies operating CBRS networks need to employ someone with a CPI, either directly or via consultancy. There are many online training courses to get certified. Make sure the training course registers you in the WinnForum CPI database and send your credentials automatically.
Castle Rock Microwave can assist you with a coverage comparison analysis or try it yourself if you are familiar with LINKPlanner (Cambium Networks) or Pathloss software.
Castle Rock Microwave is a turnkey, regional system integrator for microwave backhaul, fixed wireless broadband and WI-FI solutions for Rural Telcos, Utility Companies and Public Safety agencies. We view your wireless system as an integral part of your operation and create holistic RF designs with your entire systems, sustainability, and future business goals in mind. We are vendor agnostic and work with our clients in choosing the best solution for performance, maintainability, and budget in mind. Call us for:
Current market conditions are creating opportunities for rural telcos to expand their users and networks and in some cases with substantial grants. Wise long-term investments in the correct gear will separate the leaders from the competition. Make sure your designs are considering all the factors when deploying or optimizing your wireless network and contact Castle Rock Microwave for help at sales@castlerockmicrowave.com or call 303-358-7039.
An industry test equipment manufacturer recently estimated up to 40% of all wireless microwave paths are not aligned optimally. We believe it’s more, perhaps as high as 60%, or higher. Of course, it’s a difficult assessment to make. However, we frequently troubleshoot installation issues and have observed thousands of deployments.
Optimal antenna alignment ensures the following:
1. Regulatory and frequency coordination compliance
2. Maximized system performance
3. Predictable system availability
There are several factors that impact proper antenna alignment. First, one must consider the appropriate antenna construction and installation. Secondly, the proper mounting hardware and installation. Next, the installer and weather are taken into account. Finally, the procedures and the equipment employed to perform alignment.
In our experience, the fewer parts required to perform field installation, the better. Occasionally, we have to install antennas we don’t like. In those circumstances, it is best to build the dish in a controlled environment before transporting it to the site. This is particularly helpful when a dish comes with a lot of small parts. Following this strategy minimizes potentially costly issues while on site.
The source of the alignment problem often stems from the mounting hardware. In many cases, it’s not appropriately sized for the dish or the pipe mast is not perfectly plumb. We have found that adjusting a dish through anything other than a single plane will result in completely unpredictable results. Installers forego perfect leveling of the pipe for a lot of reasons, but here are the most likely:
* Not properly educated on the importance of a perfectly level pipe
* Improper mechanical hardware to compensate for a tapered tower or uneven mounting surface
* The wrong tools and no level
* Fatigue
* Laziness
It should be obvious that mating the correct sized pipe clamps to the correct sized pipe is necessary. Unfortunately, we often see corners being cut as a way to save time and money.
The best way to ensure the dish mounting mechanism is installed properly is to require plenty of pictures. Doing so will remove any doubt that it was done incorrectly. Most importantly, pictures of a level placed on both axes of the pipe mast proves it is indeed perfectly level. This will help rule out any issues with the mounting hardware. In addition, you should include a photo with level on the back of the dish. This will show that the dish is level.
When proper alignment becomes difficult to achieve, and all other possibilities have been eliminated, it’s time to consider the installer. It can be physically and mentally grueling to spend hours on a tower performing the same procedure over and over, and not improving the situation. Nine times out of ten, the installer and their support people on the ground resign to the frustration and lack of discipline of proper alignment and just settle for low RSL.
I have witnessed proper alignment take multiple attempts by inexperienced people, until the “right person” arrives. Of course, the more experience someone has, the better they get at it. In fact, some installers can pre-align a dish with a high degree of success using simple navigation tools like a compass and nearby landmarks.
A favorite saying I’ve heard is that, “Plan B is not Plan A, with enthusiasm”. Sometimes it’s necessary to give the project a rest and come back to it, or put a new set of eyes and hands on it.
It’s very difficult to install relatively large dishes in the wind. Likewise, dishes that sustain exposure to high winds can move over time. It’s critical that appropriate tie-back hardware is used on larger antennas. Some customers require that 3′ dishes and larger have tie-back hardware. Often 6′ dishes have two tie-backs and 8′ dishes and larger have three tie-backs. The use of tie-back hardware (sometimes called “struts”) requires forethought and planning, to ensure that all of the correct hardware is purchased in advance.
In areas where propagation is more susceptible to inversions and weather-related phenomena (varying k-factor), it is very important to perform alignment during periods of stable weather. Generally speaking, ‘good’ propagation is accompanied by wind and sun, cold fronts can be good – once they pass, warm & stationary fronts are ‘bad’. I credit my friend and colleague, Tom Hendricks for this information.
Anticipate challenges in antenna alignment when shooting over or through reflective surfaces (ie large bodies of water or between many tall buildings or a narrow canyon). With a good design the results are predictable.
We often use the microwave radio to provide fine alignment of the system. Most radios provide an indication of Received Signal Level (RSL), sometimes called RSSI. One should always be aligning to a planned RSL (dBm) value, which is derived from path planning tools or software. In addition to providing an RSL value, some radios also give audible feedback with a buzz or beep, or visual feedback with LEDs. Regardless, we generally only use these aids for course alignment and rely on an RSL measurement for fine alignment.
On occasion, the antennas are being installed before the radios are available, so the radios cannot be used for fine antenna alignment. There are some popular products available for antenna alignment under these circumstances, like the Spectracom Path alignR.
Similarly, we recently witnessed a demonstration from a company called Sunsight Instruments and their alignment tool called the AAT-08. We found it to be a highly innovative tool and seemingly valuable in terms of expediting alignment, versatility and reporting capabilities. We’re anxious to get feedback from the field about how they work.
To reiterate, the right tools need to be used. This is typically ratcheting-style wrenches and socket sets of the correct size. In addition, a small torpedo level to ensure everything is perfectly plumb prior to alignment. We often see people using digital levels. These seem to work well. Your installer should also use a marker to put an indicator on the threaded rod. This will remind them how to get back to a certain signal level.
Prior to getting on the tower or building, a course alignment can be achieved using a simple magnetic compass, adjusted for proper angle of declination. Of course, this assumes that the path azimuth is known. Google Earth can help identify nearby and distant landmarks that the installer can use to aim the dish.
We always align the antennas with no up-tilt or down-tilt, unless the path is extremely short. This is the easiest way to begin alignment if the expected tilt adjustment is less than a couple of degrees.
Only one side of the path should be adjusted at a time. In addition, everything below assumes that both dishes are on the same polarization.
Once everything is level, the azimuth should be swept. You’ll often see one or more side lobes of the antenna before you see the main lobe. This is indicated by the RSL measurement. The main lobe is often distinguishable as having approximately 20dB more signal than the nearest side lobe. Likewise, it tends to rise and fall off very sharply, where side lobes can persist longer through a sweep cycle. Also, the main lobe is accompanied by the presence of at least two side lobes on either side of it.
If you were to start a sweep on the far left side of the radiation pattern of a dish, sweeping the dish to the left (pulling the left side of the dish towards them), you should see some amount of signal gradually increase and then decrease (one side lobe). Next, you will see the signal increase more than it did with the prior lobe and then decrease (another side lobe). Finally, the signal should increase significantly (~20dB) and quickly fall off. This is the main lobe. After this, the reverse of what was just described should be witnessed as the dish continues to be swept in the same direction, until the signal completely goes away.
Commonly, installers will only see a single lobe in the entire sweep. This is seldom the main lobe and evidenced by a signal level well below (10 – 20dB) the planned RSL. A lot of time is often spent aligning both sides of the link to keep landing on the lower-than-expected RSL. This is often due to one of the issues described above. Either mounting isn’t level, there’s tilt in the dish, or adjustments are being made on both side simultaneously, etc.
Another common symptom of poor alignment is that two rises and falls of signal will be seen, but well below the expected amount. This is just more evidence of either being above or below the main lobe, or not sweeping far enough through the entire radiation pattern.
Once the main lobes of both dishes are found, the elevation should be adjusted to optimize the link. Once both azimuth and elevation are fine tuned, the RSL should meet the planned signal level dictated by the path design.
There are definitely other things that can go wrong with microwave radio links. More often than not, the problems stem from a system that isn’t optimized. The most neglected step in optimization is proper alignment.
We’d love to hear your thoughts on the matter. Please take a moment and let us know how you deal with an installer or tower crew that swears the path is “on the main lobe”, when all of the evidence points to it being on a side lobe.
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The impact of wind turbines on microwave radio paths is a bit of a mystery. It’s often misunderstood. In this blog post I’ll provide a couple planning tips and some useful reference material. My goal is helping you make good decisions about how to plan for a successful coexistence of microwave paths and wind turbines.
I planned many microwave paths near wind farms containing individual wind turbines. I also investigated performance issues caused by the these spinning behemoths near microwave paths. When it comes to planning microwave paths over rural, flat terrain, you need to consider the possibility that wind turbines could be present. In addition, you need to have a plan if they are in the vicinity of the proposed radio sites. I found that following the recommendations below made it a straightforward planning exercise.
The presence of wind farms is obvious if you’re familiar with an area or personally involved in surveying sites. However, so much preliminary work is done from a distance and often without intimate knowledge of the landscape. The USGS is an excellent resource to identify wind turbines and wind farms. They even provide a Google Earth .KMZ file which helps quickly identify any wind turbines that might obstruct the microwave path.
There are three main considerations to ensure a successful outcome when deploying microwave in the presence of wind turbines:
The impact of the first two criteria is generally manifested as reduced received signal level (RSL) from the designed plan. This generally degrades throughput performance and sometimes causes bit errors. The third item, reflections caused by the moving blades, will generally be manifested by increased bit errors and perhaps varying RSL. Don’t let the fact that the blades are seemingly non-conductive fool you. They likely contain trace amounts of copper to assist in lightning protection.
Over the past twenty years a fairly substantial amount of empirical data was collected to quantify the impact of wind turbines on analog wireless systems in the TV broadcast and radar bands. Comparatively less work has been done to collect similar data for digital transmissions in the microwave bands. However, paths can be planned with confidence using the guidance indicated in these documents; Wind Farms and Microwave Links – Harvey Lehpamer and Fixed Link Wind-Turbine Exclusion Zone Method – D F Bacon. These documents describe the general rules for exclusion zones around the path and distill it down to simple parameters. Harvey Lehpamer’s recommendation form his paper entitled Wind Farms and Microwave Links generally recommends the following:
These are approximations that vary with the path distance, frequency of the radios in the path, and size of the wind turbine
Have you ever suspected interference from a wind turbine? Please take a second and tell us what you did to resolve the problem below. Don’t forget to sign up for notification of future posts.
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