Signal strength
In telecommunications, and particularly in radio, signal strength transmitted signal is being received, measured, or predicted, at a reference point that is a significant distance from the transmitting antenna. It may also be referred to as received signal level or field strength. Typically, this is measured as signal electric field strength of voltage per length or signal power received by a reference antenna. Higher powered transmissions such as broadcasting use units of dB-millivolts per metre (dBmV/m). Very low-power uses such as mobile phones are most often expressed in dB-microvolts per metre (dBµV/m) or in decibels above a reference level of one milliwatt (eg -80 dBm).
In broadcasting terminology 1 mV/m is 0 dBm (a shortened dB(mV/m)), or 60 dBµ (often written dBu) and has no reference to the dB milliwatt, the more common use of dBm.
- Some examples
- 100 dBµ or 100 mV/m: blanketing interference occurs
- 60 dBµ or 1 mV/m: the edge of a radio station's protected area
- 40 dBµ or 100 µV/m: the minimum strength at which a station can be received
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Formula
The electic field strength can be calculated from the effective radiated power, ERP, of the antenna and it's distance, d [1](here, based on a resistance of 50Ω):
Where E is in volts per metre, and d is in metres.
Cell Phone Signals
Although there are cell phone base station tower networks across many nations globally, there are still many areas within those nations that do not have good reception. Some rural areas are unlikely ever to be effectively covered since the cost of erecting a cell tower is too high for only a few customers. Even in high reception areas it is often found that basements and the interiors of large buildings have poor reception.
Weak signal strength can also be caused by destructive interference of the signals from local towers in urban areas, or by the construction materials used in some buildings causing rapid attenuation of signal strength. Large buildings such as warehouses, hospitals and factories often have no useable signal further than a few metres from the outside walls.
This is particularly true for the networks which operate at higher frequency since these are attenuated more rapidly by intervening obstacles, although they are able to use reflection and diffraction to circumvent obstacles.
Cell phones in the U.S. operate at around 800MHz and PCS phones at 1900MHz: classified as UHF and low energy microwaves respectively. This has lead to the rapid growth in the home cellular repeater market. The more advanced models now typically include an external directional antenna and an amplifier (usually operating at 55db gain) - which is generally enough to turn a very weak signal into a clear one over the local area (from around a thousand square feet to over twenty thousand).
1 comment:
The cellular repeaters you mention have been around for years now but due to FCC regulations concerning the licensing of wireless spectrum - the Networks are prohibited from manfacturing these devices. If the networks really wanted to help their customers they would receommend these personal cellular amplifiers despite there being no financial incentive for them to do this.
See here: Why don't the cell networks offer cell phone repeaters?
The fact is that if the cell networks stood to gain from these then no doubt the situation would be like in South Korea where these repeaters are on every street corner. But with the cell networks prevented from prospering from these, it is left to small third party start ups to promote them who cannot compete with the resources of the large multi national cell companies.
The truth is, if the Networks really cared they would altruistically promote these third party products to their customers.
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