Way back when mobile phones came into existence the they coined 1G with fore thought that the cell phones were just in its inception and that there was a long way to go! That recognition proved to be such a blessing and let us innovate and keep pushing the envelop with every succeeding generation. with 1G the idea was to make a call keep that call from dropping off when a moving cell phone user moves out of range of a particular cell phone tower to another. The process of the connection getting transferred to the next cell tower is know as the “hand shake” . The cell tower is usually placed or built high enough to reach a large number of people and usually the locality get surveyed ahead of time. The cell towers come in various sizes , the femtocell is usually limited to a building, the picocell can serve up to 250 yards , the microcell can operate upto 1 mile and the macrocell can serve upto 10 miles. The amount of signal that is required for a cell phone to operate with all the functionalities that is in the modern cell phone is a minimum of -45 db and that is what all the cell phone towers are aimed to do.
The 2G is when the text part came introduced and just a voice call was not enough that the data part of the process had to be introduced as well. The more the information was getting transferred between devices the more demanding the requirement on those cell phone towers became. The 3G came along and the idea of the internet became a viability and the demand on the cell phone towers ramped up even further. With every generation the demands of the cell phone users grew and grew and now at 5G the demands are more complex and vast then ever with the introduction of Internet of things (IoT) , automated cars and more all comes with some increasing evidence that the public health might be at risk. At 5g frequency the water molecules starts to turn in its axis meaning it effects the water molecules. 90 % of the human body is water and that makes it plausible that the human body can be at some risk from various publications and studies that had been done in the recent past. With that food of though it is reasonable to assume that all these developments come at a cost.
Today is October the 5th and here are the predictions for the above 3 tickers :
1) AMD Advanced Micro Devices had a pull back from all time high the past few weeks and now looks like a side ways consolidation from here on.
The count is now at the down trend to “C” and the sqiggly red line is where I project it to go and end. since it is a triangle , it has to atleast go down to 17.11 before we can get any sort of idea as to weather it is going to be a another zigzag or continue as a triangle pattern. What I call triangle is what is traditionally called the “flats” as in a) regular flat b) running flat c) expanding flat e)
The SPY is doing exactly like i wanted and looks prime to fall again once it reaches the 50 RSI level. The target is at 254 , the next area of support to finish the 4th wave and then go up on the long 5th wave completion of the Elliott wave cycle.
Also for more in depth analysis on SPY , visit http://seismic-shock.com/uncategorized/elliott-wave-analysis-of-spy-index/
The 5G networks and all the hype about how good it is and also how revolutionary it is going to be for cellular communication. In actuality it is not about speed that is the actual advantage, it is the connectivity of devices that makes 5G as the dawn of new age when it comes to cellular communication. Cellular communication has been inching into our lives slowly but surely and I remember when it was just a flip phone and how convenient it was to store numbers in it without having to write down all your friends number and remember to carry them everywhere you went on your pocket along with the phone. The additional feature of being able to store your friends name and number was actually a great feature and little did I envision of what it has become today. Why is 5G such a big deal? Well, for the short answer with out 5G your life will completely codependent on your phone eventually. You can be single with no strings ties in a relationship or any dependence on anyone for that matter, except the cellular phone.
Since iPhone was introduced the holy grail of smart phone technology was to automate your life as much as technologically possible. The smart phone has a lot of what is know as peripheral accessories alreay loaded in it. The GPS, gyro-meter, temperature sensor, pressure sensor, camera, RFID to name a few. With the GPS your phone can tell your home thermostat to wake up from sleep mode to action mode to warm your home or even your bed if you have the means. The refrigerator can alert you with the inventory when you go grocery shopping by knowing when you are actually in the grocery shopping! This type of living would have been possible already if not for this pesky technology called 5G that was taking this long. In reality we have the technology today and it is getting deployed around the United States at a very rapid pace.
What does the 5G actually do?
Good question! 5G is all about connecting small devices and more importantly stay connected! Why is the staying connected part such a crucial aspect of this technology? For your fridge to communicate with the phones, the home thermostat, door lock, starting the car all of this is depended on these devices are able to be woken up in a moments notice so they are not expected to stay ON 24×7 putting a stress on the battery. You see with all the technological innovation, the battery and energy is still the bottle neck in this whole equation. 5G operates in very high frequncy wavelenghts that it enables for this technology to be feasible and functional. How? is making these devices being able to operate in a small frequencies means that these signal are very powerful when the devices are in close proximity meaning that it require multiple cell phone towers instead of one giant tower, it requires multiple smaller micro cell type structures and with more devices being added to this cluster means every house is going to need a cell phone signal booster.
Wifi signal is the bread and cell phone signal is the butter of our lives today. For better or worse we all have are at fault to being addicted to the devices that were meant to make our lives a little bit convenient, instead we have a situation where we feel deprived in our lives without them. Anyhoo, this is not a place to dissect and analyze if this type of life style is good or bad, but instead I want to talk about how we can feed this addition more! The days when having one wifi router was enough as long as that is the place in the house you work on your laptop, phone since being on the close proximity gave you a strong signal and that is all we needed to satisfy to get good connection for those devices. But, today with a trend of folks cutting the cable and going the cordless route has made the WiFi signal a prized commodity.
You could be paying top dollars and getting a 50 GB download speed and 10 GB upload speed from your internet provider, with out a distributing network this signal can not be utilized in a home, especially homes bigger then 1000 sq ft. Homes larger then 1000 sq ft are plenty. As per this graph below, the homes are 1000 sq ft larger then the homes those were built in 1973 on an average.
an average person lives in a 1000 sq ft area now a days and if you are more then 1 person in a household then the chances are that your home is more then 1000 sq ft. This wide area requires a wide coverage and that is why those single access points from the wifi router that we are accustomed to are not going to work for future homes. This has lead to the development of what is called a mesh network. The mesh network has more then 1 Ap’s (access points) and are connected to form a web of signal to cover the whole area. When looking for a mesh network to install in the house, figure out what is the area of coverage that is needed to be covered and how many levels that need to be covered as well.
We’re often wondering about coverage maps from AT&T, Verizon, Sprint, T-Mobile, and other carriers on a quotidian substructure.
While all the major carriers relish showing fancy colored maps illustrating their general coverage area across the US, when it comes to your categorical cell tower location, you’re on your own.
Well, not genuinely. We’re here to avail.
We will show some of the websites, apps, native implements, and signal meters that will avail you find your most proximate cell tower.
1. Ascertain Your Carrier Accommodates Your Area
It’s transpired afore. Many people either buy a second home, customarily a cabin in a remote, rural area, or an RV and find their incipient place not covered by AT&T, Verizon, or their categorical carrier. So afore hunting for cell tower maps and locations, ascertain your area is a component of your carrier’s coverage map.
Simply put in your address or zip code for your carrier:
AT&T’s Coverage Map
Sprint’s Coverage Map
T-Mobile’s Coverage Map
Verizon’s Coverage Map
Once you can substantiate your area is being covered, now it’s time to find your cell tower.
2. Websites to Find Location of your Cell Tower
These websites you can put in your zip code or address and it will tell you the exact cell tower locations. While facile and fairly transparent, there’s no way to verify if it’s 100% precise. However, it is a good commencement and when paired with the other techniques we’ll mention later, it’ll give you everything you require to ken.
AntennaSearch.com (very good, but takes some time to load)
CellReception.com (good but marginally convoluted)
OpenSignal.com (best of the bunch)
3. Smartphone Apps to Find Your Cell Tower Location
These apps utilize your location and then map out the most proximate carrier cell tower. Again, it’s hard to verify if the information is 100% precise, but it’s a nice implement to have because it gives you a general conception of nearby cell towers.
Open Signal: For iPhone | For Android (best of the bunch)
Akvelon’s Signal Finder: For iPhone | For Android
RootMetrics’ Cell Phone Coverage Map: For iPhone | For Android
4. Utilize Your Smartphone’s Antenna to Find Your Cell Tower Location (Highly Recommended Method)
Of course, your phone needs a signal to work, so why not invert engineer the process to visually perceive where the most proximate cell tower is at?
But first a short and informative explication about cell phone signal.
Cell phone signals are quantified in dB (decibels). They’re rudimentary radio waves, the AM/FM kind. All cellular contrivances operate within this standard:-50 dB to -120 dB frequency.
-50 dB is considered full vigor (full bars). -120 dB is considered a dead zone (no accommodation).
However, it’s up to each carrier to define which dB range correlates to the number of bars. Simply put, there’s no industry standard to dB signal vigor and the number of bars. What’s 1 bar on Sprint could be 3 bars on T-Mobile could be 2 bars on Verizon, despite, receiving the exact same signal and operating at the exact same speeds.
The number of bars is independent to across all carriers!
But dB readings are not subjective. They’re pristine science and math. The more proximate you are too -50 dB, the better your signal. The more proximate to -120 dB, the worse your signal. And your smartphone has the native faculty to exhibit dB readings.
Here’s Steps to Access Your dB Signal:
For iPhone Operators
1. Get into Phone Mode
2. Next you can Dial and Call *3001#12345#*
3. You’ll automatically enter into Field Test Mode
4. Drop down your notifications bar and you will visually perceive your dB reading in the left-hand corner.
For Android Operators
1. Go to Settings
2. Select General Option
3. Get into About Phone
4. You will find the option Network or Status
5. From that you should optically discern your dB Value
Once you access to your dB reading, ambulate outside the perimeter of your abode. Depending on your carrier & phone model, it takes some time for the phone to refresh, so walk gradually and probe for the number most proximate to -50 dB. After a couple of walk-throughs, you should have a very good conception which area of the house is receiving the best signal, consequently kenning the general direction of your cell tower.
5. Utilize a Signal Meter to Find Your Cell Tower Location (Best Results)
While utilizing your phone in dB mode is generally a good way to find the signal for most people, if you’re an installer, contractor, or pro who genuinely wants to be precise, then getting a signal meter is a no-brainer.
It’s a handheld contrivance that pinpoints all 3G & 4G frequencies & bands, exhibits signal vigor in dB, and accurately give cell tower direction within a 45 to 90-degree spread. Scarcely costly but worthwhile investment for professional telecom users.
6. Poor Cell Phone Accommodation? Then Learn More about Cell Phone Signal Boosters
If you’re distressed from dropped calls, slow loading internet, unsent email, and poor signal, you fundamentally have two options: depend on a landline wifi connection or boost your cellular signal.
Cell phone signal boosters are potent contrivances that reach far to the cell tower, drag in the signal initially, followed by amplifying it up to 32X, and then rebroadcast the boosted signal into your domicile or office.
Here’s an expeditious summary:
1. Boosts 3G & 4G LTE signal (up to 32 x!) for all phones & all carriers.
2. Covers up to 7,500 sq ft for consumer models, 50,000 sq ft for enterprise models.
3. Better verbalize text, and more expeditious internet. Reliable connection & accommodation.
4. Complete kit, facile install, no monthly fees.
5. More bars or YOUR MAZUMA BACK.
It’s everything you require to ken about boosting the signal in the city or in the countryside.
In disasters, rescuers usually communicate via satellite if the phone and mobile telecommunication are out. But that has drawbacks: Once the data lines are overloaded, the connection disconnects. In addition, there barely are systems available yet for moving vehicles. Fraunhofer researchers have developed a new antenna system which reliably transmits data via satellite with a high-bandwidth and which is suitable for mobile use.
Natural disasters regularly strike the world. As in the case of the tsunami in Japan or the earthquake in Nepal, electricity, and telephone lines are destroyed in this process as well. Usually, mobile communications fail over a large area because the poles are damaged. That is why during disasters, rescue services turn to their own communications technology — mostly over satellite systems. Data or phone calls are sent directly to a satellite in space and, from there, to receiving stations on Earth. As a result, the rescue workers are not dependent on the communications infrastructure on the ground.
Until recently, satellite communication has had its disadvantages. The setting up of a small satellite station in the field takes some time for example. Once built, it cannot be easily moved. Moreover, the connection breaks off when a lot of data has to be transmitted or when a thunderstorm interferes. The satellite antenna has to be aligned very precisely to the satellite — just like in the case of television. It is now virtually impossible to communicate with broadband in a moving car via satellite since the antenna constantly moves out of focus due to the movement of the vehicle, although there are some antennas available that is supposed to improve but not eliminate the problem completely.
Internet users have become accustomed to a connection which is stable and which does not just break off when a lot of data is flowing over the line. If a person watches an HD movie or uses video calling, then, at most, the picture changes. It becomes grainier, more pix elated when the data line is heavily loaded — but rarely does the connection break off completely. The reason is that Internet technology is now designed so that it can control an application like the browser or Skype in such a way that the quality of the image is reduced but the functionality is preserved.
Connection without interruptions or dropouts:
With satellite communications that are not the case today. If the line is overloaded, it breaks off easily.TV viewers know that during storms, instead of their satellite image getting worse little by little, it just disappears suddenly. In other words, satellite communication has so far been lacking a continuous technology that controls the connection quality (like with the Internet) and adapts to the current utilization of the data line. Researchers have changed the data processing so that the data rate changes depending on the situation. For this purpose, a special modem has been developed for the transmission of the data.
“In this way, we achieve a very high bandwidth of several megabits per second,” says Raschke. “Of course, we don’t approach the Gigabit streams of a solid data line, but for satellite communication, it’s a big step.” Thanks to this technology, rescuers in the future will be able to send videos of the local situation and maps quickly, and without the connection breaking off. Just like you are used to from the Internet. And even clear satellite telephone calls without dropouts will be possible.
No central station required:
So far, individual senders can only connect with each other via a central hub. However, the newly developed modem now establishes direct connections. This contributes to data security not least because the transmitter and receiver now make direct contact with each other, and the data stream is no longer running through the hub.
You don’t need to live out in the middle of nowhere to sympathize with this plight. In fact, if you live in an older building, struggling with cell phone reception is something that probably sounds all too familiar.
Fortunately, we’re lucky to live in an age where many technical problems can be solved relatively easily; and bad cell phone reception is no exception. With a reasonable sum of money and some DIY, you’ll no longer need to leave your cozy spot by the radiator and go out in the freezing rain just to text someone.
A cell phone is essentially a souped-up walkie talkie. It works by converting your voice into an electrical signal that’s transmitted to the other person via radio waves.
Of course, a cell phone’s main selling point is that it’s portable; and in order to remain portable there are limits as to how large its components can be. Advances in technology have made it possible for considerably smaller components to pack a lot of punch – we’ve sure come a long way from those enormous 1980s brick cell phones! Nonetheless, even the latest smartphones have a surprisingly short range of action.
Phone masts and base stations pick up the signal from your cell phone and transmit it onward via radio waves until it reaches the cell tower closest to your friend. From there, it’s only a short distance towards your friend’s cell phone, which re-converts the electrical signal into the sound of your awesome voice.
Radio waves are what that makes cell phones work. Without them, it would be impossible to get a good enough signal to complete most calls.
Unfortunately, they’re also quite weak. Radio waves can easily be blocked by something as simple as a large tree standing in their path. And if a lowly tree can block radio waves, just imagine the damage a hulking mass of concrete and metal can do. Older buildings weren’t constructed with cell phone reception in mind. Hell, before the early 1970s no one had even dream t of cell phones. In fact, even when the first cell phones appeared, they were mostly status symbols for business types and the super rich. No one could have possibly imagined how important they’d become to our way of life in just a few decades.
So if you have bad reception while inside, that’s probably because your home or office building is made of materials that block those all important radio waves from reaching your cell phone.
Cell phone signal boosters are devices that increase signal strength. The signal booster’s external antenna picks up an outside signal and sends it to a signal boosting amplifier that increases the signal’s strength. The signal is then transmitted to an internal antenna, which emits the boosted signal throughout the building.
As you might have realized, a cell phone signal booster can only amplify a signal – it cannot create one – so you will want to place the signal booster’s external antenna in an area where the signal is strong and stable. If the external signal is weak to begin with, there’s nothing much the signal booster can do. You will also have to be careful with the internal antenna’s placement. Place it behind a thick wall or a bulky piece of furniture, and you can pretty much guarantee it won’t work as advertised.
Lots of people are dropping their home phone landlines and just using their cellphones to communicate. This might seem like a great money-saving idea, but there are some drawbacks you need to think about. Our calls do drop out, text messages get stuck and never send or perhaps our Internet browsing slows to a crawl. Someone else had excellent coverage with one provider, but then switched carriers for a new plan. Only then did she find out that her new phone rarely connected inside her home. If you are going to use your cellphone as your primary phone, you really need better reliability than that.
Some buildings seem like they were designed to block your reception. It might be a particular room, a certain spot or anywhere you stand. There’s not much you can do about poor reception when using your phone at the store or work, but at home, you don’t have to put up with it.
There are plenty of ways where one can actually boost cellphone signal inside home. With a stronger signal, you can feel free to walk from one room to another while talking or be confident that your text messages will actually send.
A third-party company like zBoost or weBoost makes boosters that do work with multiple carriers. However, you’re probably going to have to pay for this out of pocket. On the lower end, these gadgets set you back about $200. Plus, if you want higher-speed 4G coverage, count on those booster price tags bumping up to $400 or more. However, 4G is mainly an advantage only if you use your phone for Internet connections. But if you have Wi-Fi at home, you can use your home Internet connection on your phone and not need the more expensive 4G booster.
99% of the people in today’s world have a Wi-Fi wireless network already set up at home, and hopefully you’re already using it for home Internet access on your smartphone and tablet. It’s a smart way to save money on your cellular data plan and avoid overages.
Wi-Fi can also make calls and send texts using apps like Skype, Google Hangouts, Apple’s iMessage and other third-party messaging apps like WhatsApp and TextPlus. So if you don’t have a signal, it’s no worry. However, carriers and manufacturers are now exploring seamless Wi-Fi calling.
T-Mobile, for example, has Wi-Fi calling on its latest phones (and you can activate it on some older models). When you have a poor signal, it will automatically switch over to a nearby open Wi-Fi network so you won’t even notice. Expect AT&T, Verizon and Sprint to start offering this soon.
If interested one can as well switch to a phone system like Republic Wireless that has Wi-Fi calling as a main feature. Republic Wireless offers incredibly low-cost plans because it mostly relies on Wi-Fi for calling and texting and only uses cellular when Wi-Fi isn’t available. Again, the switch is seamless.