Communications: directive radio wave systems and devices (e.g. – Directive – Position indicating
Reexamination Certificate
1999-10-05
2001-10-09
Phan, Dao (Department: 3662)
Communications: directive radio wave systems and devices (e.g.,
Directive
Position indicating
C342S457000
Reexamination Certificate
active
06300905
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to location or position determination, and more specifically to location or position determination of a wireless mobile unit.
2. Description of the Related Art
Prior art
FIG. 1
illustrates a known method for determining a location from which a mobile caller originates a call on a wireless mobile unit
2
. Specifically, a call originating from the wireless mobile unit
2
reaches at least one cellular base station, such as base station
4
. The signal of the call also typically reaches to a second base station
6
and a third base station
8
. Base stations
4
,
6
and
8
record the time at which a signal arrives from a wireless mobile unit
2
. Methods for using these times to determine such a location of the wireless mobile unit
2
include both time difference of arrival (TDOA) and time of arrival (TOA) methods. These two methods are explained as follows.
Utilizing a known time of arrival (TOA) method as shown in
FIG. 1
, a first distance “a” between the wireless mobile unit
2
and first base station
4
is estimated; a second distance “b” between the wireless mobile unit
2
and second base station
6
is estimated; and a third distance “c” between the wireless mobile unit
2
and third base station
8
is estimated. Based on the time that it takes for the wireless signal to reach each of the base stations, the approximate distances “a”, “b”, and “c” are determined using the known TOA method, as follows.
As shown in
FIG. 1
, three circles are indicated, one around base station
4
, one around base station
6
, and one around base station
8
. Each of the circles encircle the wireless mobile unit
2
and represent coverage areas of the base stations. The distances a-c from the base stations to the wireless mobile unit
2
are represented by the following three equations:
((
x−x
1
)
2
+(
y−y
1
)
2
)
½
=a=C
(
t
1
−
T
)
((
x−x
2
)
2
+(
y−y
2
)
2
)
½
=b=C
(
t
2
−
T
)
((
x−x
3
)
2
+(
y−y
3
)
2
)
½
=c=C
(
t
3
−
T
)
In the above-mentioned equations, the coordinates of the wireless mobile unit
2
are represented by (x,y); the coordinates of base station
4
are represented by (x
1
,y
1
); the coordinates of base station
6
are represented by (x
2
,y
2
); and the coordinates of base station
8
are represented by (x
3
,y
3
). Further, t
1
, t
2
, and t
3
represent half of the round trip delay (RTD) time of signals traveling from base station
4
, base station
6
, and base station
8
, respectively to wireless mobile unit
2
and back. Finally, T is the processing time of wireless mobile unit
2
and C is the speed of light. Utilizing the known TOA method of detecting a location of a wireless mobile unit
2
, the absolute time of the signal traveling from the wireless mobile unit
2
to the various base stations is measured to find the distances a, b and c and to eventually arrive at an approximate (x,y) location for the wireless mobile unit
2
. However, the clock in the wireless mobile unit
2
may not exactly be synchronized with that of the various base stations
4
,
6
, and
8
, thus making it difficult to determine the aforesaid absolute time. To compensate for clock synchronization problems, absolute time is measured by a round trip delay in the time of a signal sent from a particular base station to the wireless mobile unit
2
and back to the base station. However, round trip delay includes processing time in the wireless mobile unit
2
that needs to be estimated. Normally, it can be estimated based on the knowledge of a particular brand of the wireless mobile unit
2
.
Another known option for deter mining a location of a wireless mobile unit
2
is to use a time difference of arrival (TDOA) method. TDOA measures the time difference of arrival for signals from the wireless mobile unit
2
to two or more base stations. Hence, the timing factors in the wireless mobile unit
2
are cancelled from the TOA equations expressed above. Assuming that the processing time of the wireless mobile unit is small or known, however, TOA can still be used.
FIG. 2
illustrates an example of a TDOA method. The hyperbola “ab” is constructed using the TDOA between base station
6
and base station
4
, in reference to the wireless mobile unit
2
. Further, the hyperbola “cd” is constructed by using the TDOA between base station
6
and base station
8
, in reference to the wireless mobile unit
2
. The hyperbolas are determined, with the same coordinates and values previously expressed using TOA, based upon the following equations:
((
x−x
2
)
2
+(
y−y
2
)
2
)
½
−((
x−x
1
)
2
+(
y−y
1
)
2
)
½
=C
(
t
2
−
t
1
)
((
x−x
3
)
2
+(
y−y
3
)
2
)
½
−((
x−x
2
)
2
+(
y−y
2
)
2
)
½
=C
(
t
3
−
t
1
)
Using these equations, the (x,y) position of the wireless mobile unit
2
is determined.
Accordingly, with these known methods, TOA and TDOA can be used in an ideal situation to determine a location of a wireless mobile unit
2
. However, as shown in
FIGS. 1 and 2
, both the TOA and TDOA methods require the detection of a signal(s) transmitted to/from at least three base stations,
4
,
6
and
8
in order to utilize their methods to determine the location of a wireless mobile unit
2
. In some instances, however, the signal cannot be detected by all three base stations
4
,
6
and
8
. An example of this situation is shown in prior art FIG.
3
.
The known TOA and TDOA methods of detecting a location of a wireless mobile unit
2
, in many instances, only provide an estimated location. Additionally, if all three base stations are not detected, the estimated area of location cannot even be detected.
For example, as shown in prior art FIGS.
3
(
a
) and
3
(
b
), barriers such as buildings, for example, can block signals from being received by base stations. Accordingly, although the cellular call from wireless mobile unit
2
may still be able to go through, only a single base station may detect the call. If only two of the three base stations (
6
and
8
as shown in FIG.
3
(
a
) for example) can be detected, only two distances such as “b′” and “c′”can be calculated, resulting in non-unique solutions. If only one or two base stations can be detected, the location of the wireless mobile unit
2
can only be roughly estimated, at best.
As shown in FIG.
3
(
a
) for example, if only two base stations
6
and
8
are identified in a TOA system, then only two circles can be determined and only a parabolic area
10
can be estimated as the approximately location of a wireless mobile unit
2
. Similarly, if only base stations
6
and
8
are identified in a TDOA system, as shown in FIG.
3
(
b
), only one parabola “cd” can be calculated and the location of the wireless mobile unit
2
can only be roughly estimated at best.
Accordingly, there is a need for a better system and method for determining the location of a wireless mobile unit
2
, and especially using only a single base station.
SUMMARY OF THE INVENTION
A method and apparatus have been developed for determining a location or position of a wireless mobile unit using only measurements from a single base station. A distance between the wireless mobile unit and the base station is calculated utilizing a round trip (RTD) delay value of a signal received from the wireless mobile unit. Thereafter, an angle of arrival (AOA) of the received signal is determined using measurements of the received signal from each of a plurality of antenna sectors of a multi-sector antenna. The angle of arrival is determined based upon stored antenna signal measurements of the multi-sector antenna, wherein a combination of different sector signal measurements corresponds to a single angle measurement. Using the determined distance and angle of arrival, a position or location of a wireless mobile unit can easily b
Chen Byron Hua
Chiang Tung Ching
Tekin Ibrahim
Lucent Technologies - Inc.
Phan Dao
LandOfFree
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