The average person can notice the effects of changes in radio propagation in several ways. In
AM broadcasting, the dramatic ionospheric changes that occur overnight in the mediumwave band drive a unique
broadcast license scheme in the United States, with entirely different
transmitter power output levels and
directional antenna patterns to cope with skywave propagation at night. Very few stations are allowed to run without modifications during dark hours, typically only those on
clear channels in
North America. Many stations have no authorization to run at all outside of daylight hours. For
FM broadcasting (and the few remaining low-band
TV stations), weather is the primary cause for changes in VHF propagation, along with some diurnal changes when the sky is mostly without
cloud cover. These changes are most obvious during temperature inversions, such as in the late-night and early-morning hours when it is clear, allowing the ground and the air near it to cool more rapidly. This not only causes
dew,
frost, or
fog, but also causes a slight "drag" on the bottom of the radio waves, bending the signals down such that they can follow the Earth's curvature over the normal radio horizon. The result is typically several stations being heard from another
media market – usually a neighboring one, but sometimes ones from a few hundred kilometers (miles) away.
Ice storms are also the result of inversions, but these normally cause more scattered omnidirection propagation, resulting mainly in interference, often among
weather radio stations. In late spring and early summer, a combination of other atmospheric factors can occasionally cause skips that duct high-power signals to places well over 1000 km (600 miles) away. Non-broadcast signals are also affected.
Mobile phone signals are in the UHF band, ranging from 700 to over 2600 MHz, a range which makes them even more prone to weather-induced propagation changes. In
urban (and to some extent
suburban) areas with a high
population density, this is partly offset by the use of smaller cells, which use lower
effective radiated power and
beam tilt to reduce interference, and therefore increase
frequency reuse and user capacity. However, since this would not be very cost-effective in more
rural areas, these cells are larger and so more likely to cause interference over longer distances when propagation conditions allow. While this is generally transparent to the user thanks to the way that
cellular networks handle cell-to-cell
handoffs, when
cross-border signals are involved, unexpected charges for international
roaming may occur despite not having left the country at all. This often occurs between southern
San Diego and northern
Tijuana at the western end of the
U.S./Mexico border, and between eastern
Detroit and western
Windsor along the
U.S./Canada border. Since signals can travel unobstructed over a
body of water far larger than the
Detroit River, and cool water temperatures also cause inversions in surface air, this "fringe roaming" sometimes occurs across the
Great Lakes, and between islands in the
Caribbean. Signals can skip from the
Dominican Republic to a mountainside in
Puerto Rico and vice versa, or between the U.S. and British
Virgin Islands, among others. While unintended cross-border roaming is often automatically removed by
mobile phone company billing systems, inter-island roaming is typically not. ==Empirical models==