Over the past few years, astronomers have detected thousands of planets and
candidate planets by observing their periodic transits in front of their host
stars. Related methods might soon allow studies of the chemical imprints of
life in extrasolar planetary atmospheres. Here, we address the reciprocal
question, namely, from where is Earth detectable by extrasolar observers using
similar methods. We explore Earth's transit zone (ETZ), the projection of a
band around Earth's ecliptic onto the celestial plane, where observers can
detect Earth transits across the Sun. The ETZ is between $0.520^\circ$ and
$0.537^\circ$ wide due to the non-circular Earth orbit. The restricted ETZ
(rETZ), where Earth transits the Sun less than 0.5 solar radii from its center,
is ~$0.262^\circ$ wide. We first compile a target list of 45 K and 37 G dwarf
stars inside the rETZ and within 1 kiloparsec (3260 lightyears) using the
Hipparcos catalog. We then greatly enlarge the number of potential targets by
constructing an analytic galactic disk model and find that ~$10^5$ K and G
dwarf stars should reside within the rETZ. The ongoing GAIA space mission can
potentially discover all G dwarfs among them (several $10^4$) within the next
five years. Many more potentially habitable planets orbit dim, unknown M stars
in the ETZ and other stars that traversed the ETZ long time ago. If any of
these planets host intelligent observers, they could have identified Earth as a
habitable, or even as a living, world, and we could be receiving their
broadcasts today. The K2 mission, the Allen Telescope Array, the upcoming
Square Kilometer Array, or the Green Bank Telescope might detect such
deliberate extraterrestrial messages. Ultimately, the ETZ would be an ideal
region to monitor by the Breakthrough Listen Initiatives, an upcoming survey
that will constitute the most comprehensive search for extraterrestrial
intelligence so far.