tawkon: How We Help Avoid Mobile Radiation
The mobile software industry is continuing to amaze experts with its astonishing numbers of independent mobile applications and downloads. However, as a result of the increasing functionality our phones now provide, we felt that there was a need for a solution to one of the most well-known side effects of intense mobile phone usage. Mobile phone radiation is a topic we hear a lot about, but the practical solutions are far less common.
We therefore set out to become the leading software provider for a real time and accurate mobile tool that will notify users of increased radiation and offer them practical and convenient ways to reduce their exposure. We worked for over a year and a half developing tawkon for multiple mobile platforms such as iPhone, BlackBerry, and others.
While the BlackBerry version was released just last week to the public, the iPhone app has not yet been approved by Apple. With the release of the BlackBerry version, we received tremendous compliments and positive feedback from some of the industry’s leading personalities. However, we started noticing a trend, primarily in the Comments section of the various articles covering tawkon. Many people were skeptical regarding the technological side of the app, and some even went as far as to call it a scam. The premise of these claims was that modern smartphones do not have the capability to measure radiation, leaving no way for tawkon to possibly know the precise levels of radiation phones are emitting.
To be honest, we all use many different technologies in our day to day lives, and rarely do we understand the technical aspects of how these technologies work. However, when it comes to our personal health and a topic as “hot” as mobile phone radiation, people want to know how it works, and this is very much justified. We therefore decided to write this post and try to break down the technology behind tawkon, and how it all really works. We will of course try to simplify it for those that are not radiation experts, but bear with us, the information is all here.
Cellular Communication: How Does it Work?
Before we delve into what we have been working on for the past year and a half, it is important to understand how cellular technology works, at least on its most basic level. Mobile phones allow communication from any location via a network of cellular towers. Information is transmitted from the mobile phone to the cellular tower and vice versa via high-frequency electromagnetic fields.
The mobile phone is comprised of hundreds of electronic components. The heart of the system is the modem (baseband), which is responsible for the wireless communication (similar to the DSL modem most of us have at home). During the communication process, the mobile phone gets instructions from the cellular network of how much energy it should transmit in order to keep the voice or data session in good quality. The more energy the phone utilizes, the more mobile radiation it emits.
Mobile Phone Non-Ionizing Radiation, SAR and Radiation Exposure
The energy transmitted during the communication between a mobile phone and a cell tower is actually non-ionizing radiation. Its values range from 250mWatts for third generation networks (3G) to 1.8 Watts for second generation networks (2G). (1mWatt = 1/1000 Watt)
So what does all this mean? It means our phones emit a certain amount of radiation when in normal use, but the radiation the phone emits does not equal the radiation to which we are exposed. There are many other variables to that equation.
The following are some of the factors that affect the actual levels of radiation to which we are exposed to when using mobile devices:
- Hardware: The way a mobile device is engineered, the model of the phone, factors such as the location of the device’s antenna, the materials out of which it was constructed, materials that physically shield the device from the cellular network (covers, sticker, etc) as well as the shape and size of the phone are all components that affect your levels of exposure to radiation.
- Environment: The location of the mobile phone is a crucial point. The terrain (whether the user is shielded from the cellular network e.g. in a basement, elevator or behind a concrete wall), mobility (due to frequent handover between cell towers) as well as weather conditions are all characteristics that are factored into this equation.
- Usage: While the above two factors are not in the hands of the user (besides of course selecting a device and changing location when possible), the way we use our phones very much depends on us. Many people are unaware that even the smallest adjustment in the way we operate our mobile devices can drastically reduce our exposure to mobile phone radiation. Holding the phone vertically and not horizontally, distancing the device from ones body & head via peripherals such as headsets (wired or Bluetooth) or by using the phone’s speaker, we can actively take part in lowering our exposure to radiation.
The amount of mobile phone non-ionizing radiation we are exposed to is measured in units called SAR (Specific Absorption Rate). Each mobile phone vendor has to comply with the FCC regulations of maximum SAR levels of 1.6Watt/kg. You can see what your device’s SAR level is here.
What most people do not know is that SAR levels of mobile phones are dynamic and change constantly (from zero to the max SAR values of the specific phone model) based on the factors we mentioned above.
tawkon– How Does It Work?
All the information related to the radiation emitted by the mobile phone is available / stored in the phone itself. This information is required by the phone for its normal operation as it needs to know how much power to transmit in order to keep the voice or data connection while the user is talking or on an active data session (browsing, VOIP, etc).
tawkon extracts this information in the form of different RF and network parameters such as: Network – whether the phone is connected to second (2G) or third generation (3G) network, Band – each phone model supports different bands e.g. GSM (850, 900, 1800, 1900Mhz) or WCDMA (850, 1900, 2100Mhz, etc) and many others.
All of these parameters in addition to various other smartphone capabilities such as motion and proximity sensors, GPS and compass are inputs to tawkon’s patent pending technology that presents the user his exposure to non-ionizing radiation.
The patent-pending RF component of the tawkon technology was developed and tested by, and in collaboration with In4Tel Ltd, a tawkon strategic partner.
What does it take to distribute new phones to the market running tawkon?
Each phone model we support goes through an intense calibration process in an RF lab. This is to ensure that the application on the specific phone model is accurate and precisely reflects the actual exposure of the user to the non-ionizing radiation. The measurements and calibration of the application are conducted with the most sophisticated equipment used by leading mobile phone vendors in the industry. These tools include base station simulators, SAR measurement systems, and other equipment used in the process of certifying phones for the consumer market.
Final Words
As we said above, our goal here was to lay out some of the fundamental principles that guided us in our development of tawkon.
Now that we have covered the basics of the technology behind tawkon, we hope you can recognize that this is a unique and effective tool in our battle to benefit from mobile technology while eliminating associated risks.
We wrote this in light of some skeptical comments we received. We encourage your feedback and insights on our mobile application and know that with the help of your opinions, we will continue working hard on making tawkon as great as we know it can be. Our ultimate goal is to enable mobile users across the globe to benefit from mobile technology and utilize it as a resource that will enhance our daily lives, which is what mobile devices were intended to be in the first place.
Amit Lubovsky,
Co-Founder & VP, R&D tawkon
I write this in light of some skepticism.
Although a very interesting product, tawkon to me equals business and marketing only. While I couldn’t spot errors in your claims and all seems fact, it is common knowledge what is presented and contributes little to the functionality behind your product. What you give us is a brief and short summary of what components of a phone tawkon uses as input, but fail to provide more information as to how all calculations and formulae inside the application work. What makes me even more skeptical is the company In4Tel Ltd, of which little information is available on the Internet. Being a strategic partner of tawkon I can see it lying in the same bed as tawkon greedy for money and not providing the end user a true product.
If you want to prove me wrong or convince me you have a real product to offer, answer this single question to me: how will the lack of GPS affect the accuracy of tawkon? Not all BlackBerry smartphones have GPS built in, but you mentioned that tawkon may use it as an input. Now in order for your answer to truly be credible you must first explain me and everyone else how GPS as an input paremeter works within tawkon and how will the lack of GPS support affect the accuracy of tawkon. I believe you will be answering me with the usual “to determine proximity to cell towers” card, but I want you to provide me the formula you used in programming level. Show me.
[...] to now work with the 9000, 8900 and 85xx series of devices, and they have also provided a more in-depth look at the inner workings of the application, for those skeptics needing proof that it isn’t just [...]
[...] radiation’s impact on health. If you’re interested be sure to check it out as well as their blog post about how they help avoid mobile radiation. Tawkon’s BlackBerry app will be available in the [...]
First thanks in the interest you take with tawkon.
tawkon technology was developed over 18 months by tawkon and In4Tel which is a leading RF lab with a lot of expertise in the cellular space (although not mentioned a lot in the internet, due to business considerations). As you can probably understand, the algorithms and formulas inside the application are patent pending and therefore we are not publishing them.
For users the key factor is the accuracy & reliability of our output. This is being achieved by testing and calibrating in an RF lab each client (phone model) we release to the market. In order to take into consideration the different SAR levels that differ from mobile to mobile (as I assume you probably know), calibration is being done with the same equipment as the phone vendors use in order to comply with the FCC regulations,
As an example, follows the link to the FCC report (RF Exposure Report) for the BlackBerry Bold 9700, (check out for the Dasy4 SAR measurement equipment)
https://fjallfoss.fcc.gov/oetcf/eas/reports/ViewExhibitReport.cfm?mode=Exhibits&RequestTimeout=500&calledFromFrame=N&application_id=711021&fcc_id=%27L6ARCM70UW%27
Without revealing our IP we can share there are three inputs to the algorithm that calculates the user exposure to radiation:
1. Dynamic SAR values of the phone – these values are calculated based on different RF parameters extracted from the phone cellular protocol stack (modem/baseband)
2. User behavior – under this category there are all the phone capabilities you have mentioned such as GPS, accelerometer, Bluetooth and other audio routes, proximity sensor, etc
3. Network condition – e.g. reception level, terrain, coverage, etc which dictates the quality of the wireless channel
Regarding your valid comment on GPS;; the GPS is not used as an input parameter to our SAR calculation it’s only being used in order to advise the users to talk in a location with less exposure to radiation.
During a call we log the user’s location (GPS) and the exposure to radiation, in cases when the user used to be in a location with less exposure and moved to a location with higher exposure we notify and suggest the user to move back to its previous location.
Generally speaking, our suggestion/feedbck mechanism is based on the specific device capabilities, on BlackBerry’s without GPS tawkon won’t give the user this suggestion.
I hope that I have answered your questions, would be great to further get your feedback once you use our application.
Amit Lubovsky, Co-Founder & VP R&D
[...] Download screenshots or view tawkon in action here. And if you would like to try/review tawkon for yourself, please send me your UDID and I’ll send you the files of a complementary version. Read about the technology behind the app here. [...]