CA2191805A1 - Apparatus and method for transmitting a signal - Google Patents

Abstract

A method and apparatus for initiating a telecommunications call. A plurality of beacons (102,) are geographically disposed in a telecommunications system (100). Each beacon (102n) radiates an electromagnetic carrier that is modulated with an identifying address (e.g., a telephone number, an Internet address) for an associated terminal. An identifying signal is stored in a memory (206). A controller (208) modulates a carrier with the identifying signal and a transmission element (210) transmits the carrier to allow a communications terminal (104) to initiate a call to the associated communications terminal (114, 116). A wireless terminal (104a) includes a directional receiver (204). To initiate a call, a user points directional receiver (204) at a beacon. The directional receiver (204) receives the electromagnetic carrier and the wireless terminal recovers the identifying address. Wireless terminal (104) then uses the identifying address to initiates a call, in well-known fashion, to the communications terminal associated with the identifying address.

Description

2 i 9 1 8û5 APPARATUS AND METHOD FOR TRANSMITTING
A SIGNAL

Field of the Invention The invention relates to telecomm~nic~tions in general and, more particularly, to a method and appaldlus for transmitting a signal.

DescriDtion of the nelotell Art s Telecommunications influences the personal, social and business affairs of people everyday. Over the past few dec~des, the telecommllnic~tions industry has made significant strides toward the goal of making their services available to anyone, anywhere and at anytime. These services have e~p~nded through advances in wireless, broaclb~nd and multimedia telecornmunications. In each of these areas, the most persistent obstacles to continued expansion arise from human factors. For example, one such obstacle is how to devise telecommunications equipment that will comlecl a caller to any party he or she wishes to be connected to at the moment he or she wishes to be connected.
Although people often conceive, and colloquially speak of, calling another person, a telephone system conventionally routes a call to a telephone and not, strictly spe~king, to the desired person. But because the telephone system can only connect a call to a telephone and not to a person, a functional gap exists between what callers generally desire to do and what the telephone system enables them to do.

S~ mn or~ of the Invention The invention is as defined by the claims. Embo<lim~nt~ of the invention provide a method and apparatus for conveying an identifying signal (e.g., a telephone number, an Internet address) to a user to initiate a call (whether voice, video, data or multimedia) while avoiding many of the costs and restrictions associated with conventional techniques.
More specifically, embodiments of the invention transmit an electromagnetic carrier modulated with the identifying signal of an associated communication terminal (e.g., a wireless termin~l, a wireline terminal, an automatic call distribution system) for receipt by a second co.~ nication termin~l. The second co---.-~.-nic~tion terminal can, for example, use the identifying signal to initiate a call to the communir~tion termin~l associated with s the embodiment.
An illustrative embodiment of the invention comprises a beacon that transmits a signal that identifies one or more comml-nication t~P.rmin~lc. A beacon typically comprises a controller that drives a tr~ncmiccion element to radiate an electrom~gnP,tic carrier having modulated thereon an identifying signal of its associated commllnications terminal. In 0 some embo~limp-ntct the beacon advantageously includes a receiver for use in remotely modifying the identifying signal for the beacon. Further, in other embodiments, a power source, such as a solar cell, advantageously provides power to beacons that operate in remote locations.
One or more commnni~tion terminals that include a directional receiver are used for receiving the signal from the beacons. The directional receiver is capable of receiving the electromagnetic carrier. A processor in the comml-nic~tion terminal is capable of recovering the identifying signal from the electromagnetic carrier, and initi~ting a call in well known fashion based on the identifying signal.
For example, an automobile cont~ining a cellular telephone could have mounted byeach license plate an embodiment of the invention that radiates the telephone number of the cellular telephone in the automobile. If a user of a cellular telephone with a directional receiver desires to call that automobile, the user can point the directional receiver at one of the beacons to receive the identifying signal and initiate a call to the cellular telephone in the automobile.
2s Alternative emb~liment.c of the invention provide a method and app~dlLIs for initi~ting a telecommunications call (whether voice, video, data or mllltim~ ) while avoiding many of the costs and restrictions associated with conventional techniques.
Specifically, ~ltern~tive emb~im--ntc of the invention enable the initiation of a teleco.. i~ tions call to a comml-nication terminal (e.g., a wireless termin~l, a wireline terminal, an automatic call distribution system, etc.) based on the reception of an identifying address (e.g., the telephone number, the Internet address) of the con~ nic~tions termin~l via a directional receiver.
~lustlati~ely, an ~l~rn~tive embodiment of the invention comprises a wireless termin~l that is operably connected to a directional receiver and operates in conjunction with one or more beacons. The directional receiver is capable of receiving the electromagnetic carrier. A processor in the alternative embodiment is capable ofrecovering the identifying signal from the electrom~gn~tic carrier and initi~ting a call, in o well-known fashion, based on the identifying signal.
For example, an automobile con~ining a cellular telephone can have mounted by each license plate a beacon that radiates the telephone number of the cellular telephone in the automobile. If a user of this ~ltern~tive embodiment desires to call that automobile, the user can point the directional receiver at one of the beacons to receive the identifying s signal and initiate a call to the cellular telephone in the automobile.

Brief DescriDtion of the Drawin~
Illustrative embodiments of the invention are described with respect to the following drawings, wherein:
FIG. 1 depicts a schematic diagram of a portion of a telecommllnications system that intelopeld~es with one or more embodiments of the invention;
FIG. 2a depicts a block diagram of a beacon for use in the telecommunications system of FIG. l;
FIG. 2b depicts a block diagram of a wireless terminal for use in the telecommllnications system of FIG. l;
FIG. 3 depicts a side elevational view of a beacon for use in the telecommnnications system of FIG. l;
FIG. 4 depicts a top view taken along line 4-4 of the beacon of FIG. 3;

FIGs. S through 7 illustrate other embo-liment.c of the invention that can intero~rdte with the telecomml-nications system of FIG. l;
FIG. 8 is a block diagram of an embodiment of a directional receiver;
FIG. 9 is a block diagram of another embodilll~.lt of a directional receiver;
s FIG. 10 is a block diagram of an embodiment of the input/output associated with the embo lim~ont in FIG. 2;
FIG. 11 is an isometric diagram of another illustrative embodiment of the invention;
FIG. 12 is an isometric diagram of another illustrative embodiment of the l o invention;
FIG. 13 is an isometric diagram of another illustrative embodiment of the invention; and FIG. 14 illustrates a method for using an illustrative embodiment of the invention.

Detailed DescriPtion FIG. 1 is a block diagram of telecomlllunications system 100, which intero~ld~eswith one or more embo limPnt.~ of the invention. Telecommllnis~tions system 100 illustratively comprises public switched telephone network ("PSTN") 106, wireless telecommunications system 108, and computer network 107. Wireless telecommunications system 108 includes wireless switching center ("WSC") 110 and base stations 112l, 1122 and 1123, which are geographically dispersed throughout the region serviced by wireless teleco,ll",.mications system 108. Further, telecommunications system 100 includes a paging system with paging tr~n~mitter 118.
The illu~a~i~e embodiment comprises one or more "beacons" (e.g., beacons 102"
1022, ..., 102n). Each beacon 102i advantageously radiates an electromagnetic carrier that 25 is modulated with data including, among other things, an identifying signal (e.g., a telephone number, an Internet address) of an associated communication termin~l that is ~ces~ihle via telecommunications system 100 and addressable by the identifying signal.

21918~5 Paging tr~ncmittt~r 118 can provide a signal to a beacon to remotely modify, for example, the identifying signal for the beacon as described more fully below. The details of where beacon 102j is located and what information it radiates will be discussed below.For the purposes of this specification, a "commllnications t~rmin~l" includes, but is S not limited to, any device that is associated with an identifying address (e.g., a wireless tçrmin~l, a wireline terminal, an automatic call distribution system), and a "wireless terminal" includes, but is not limited to, a wireless telephone or videophone, a wireless fax m~chinç, a wireless computer. Also for the purposes of this specification, a "wireline terminal" includes, but is not limited to, a wireline telephone or videophone, a wireline fax o machine, a wireline computer.
Communication t~rmin~l 104 includes a directional receiver that receives the electrom~gn~tic carrier from a beacon such as beacon 102,. Commllnication termin~l 104 uses the identifying signal from the electrom~gneti~ carrier to initiate a call to, for example, terminal 116 or terminal 114.
FIG. 2a depicts a block diagram of an illustrative embodiment of the invention ~çsig~te~l generally as beacon 102a. Beacon 102a includes tr~ncmi.ccion element 210 that transmits an electromagnetic carrier modulated with data. The frequency of the electrom~gnetic carrier is advantageously chosen so that: (1) absorption of the electromagnetic carrier by glass (e.g., automobile window glass), clothing and animal tissue is sufficiently small so that unacceptable attenuation of the electromagnetic carrier does not occur, and (2) the diffraction of the electrom~gn~tic carrier around everyday objects is kept low.
The reason that it is advantageous for absorption by glass to be sufficiently small is that it enables a user with a directional receiver that is separated from a beacon by a glass 2s window and who can see the beacon to be able to receive the electrom~gn.qtic carrier. The reason that it is advantageous for absorption by clothing to be sufficiently small is to enable the electromagnetic carrier to be received by a user when the beacon is on or in someone's clothing (e.g., an inside coat pocket). The reason that it is advantageous for ., 21ql~05 absorption by animal tissue to be sufficiently small is to enable the electrom~gn~otic carrier to be received when a human is interposed between the beacon and the directionalreceiver. The diffraction of the electromagnetic carrier should be kept low so as to reduce the likelihood that an electromagnetic carrier could be received from a beacon whose 5 existence is not known to the user.
Tr~n~mi~ion element 210 advantageously may comprise, for ex~mrle, a light emitting diode or other radiator. Controller 208 of beacon 102a generates the modulated electrom~gn~-tic carrier with data from memory 206. As shown in Table 1, below, the data m~~ ted onto the electromagnetic carr~er may include "user data" and "tr~n~mi~sive o data" as well as the identifying signal.
Example Identifying Signal User Data ~ ive Data No.
207-773-0796 Police Serial. No.4444 2207-799-0553 McDonald's 2 Miles --ahead 31-800-555-1212 --45 35' 7" N. 78 4' 13" E.
4 402-0932 Fax. --Table 1 - Examples of Information Broadcast by a Beacon The user data is data that can be output to the user of a communication terminal .
that receiws the electrom~netic carrier from beacon 102a. In Example No. 1, the communication terminal may display "Police" or convert the text to speech. It is noted s that the user data is not limited to text. Rather, the user data may comprise video, audio, or a picture. Further, tr~n~mi~ive data can include, for example, the latitude and longitude of the beacon, or the serial number of the beacon that can be tr~n~mitted by a communication terminal to the communication termin~l associated with the beacon as part of the call.

Controller 206 advantageously encodes the identifying signal, the user data and tr~ncmiccive data into a data structure that can be unambiguously parsed by the receiver of the electromagnetic carrier. Controller 206 also advantageously encodes the identifying signal, user data and tr~ncmiccive data to provide a mea~ul~, of error correction and/or s detection, and can encrypt the identifying signal, user data and tr~ncmiccive data to facilitate privacy. Furthermore, controller 206 provides a synchronization signal so that the receiver can acquire the data and modulates the idenlirying signal, user data and tr~ncmiccive data in well-known fashion (e.g., quadrature phase shift keying, binary phase shift keying).
0 Beacon 102a can be preprogr~mm~l, for example, by the factory or dealer selling the beacon or by the owner of the beacon prior to setting the beacon up for use. For example, the beacon can be distributed or sold individually or as a package with a communication terminal. When distributed as a package, a dealer can pre-store the identifying address of the wireless termin~l at the same time that the wireless termin~l is s ~cci~nçd a telephone number. A user of the communication termin~l can then set up the corresponding beacon at a desired location.
The data in memory 206 of beacon 102a may be remotely modified. Beacon 102a includes transceiver 204 that is coupled between ~ntenn~ 202 and memory 206.
Transceiver 204 may comprise a one-way or two-way pager as are well-known in the art.
Antenna 202 and transceiver 204 receive an electrom~gn~qtic carrier modulated with the new data for beacon 102a from, for example, a paging network. The new data is stored in memory 2()6 and used by controller 208 to generate the modulated electrom~gn~tic carrier signal for beacon 102a. Transceiver 204 can also transmit a confirmation signal to the paging network that the new data has been received.
2s Beacon 102a advantageously comprises power source 212, such as a solar cell and battery, that is coupled to provide power to transceiver 204, memory 206, and controller~
208. By using a solar cell and battery, beacon 102a can be used in remote locations that lack an electrical outlet. Alternatively, power source 212 can be a replaceable battery source or an AC to DC converter for converting a household line voltage to voltages suitable for driving the electronic circuitry. Various combinations of these and other types of power sources can be used for powering the beacon.
FIG. 2b depicts a block diagram of commllnication terminal 104a, which is capable of being a wireless terminal. Wireless termin~l 104a comprises processor 202 that is comml-nic~tively coupled to directional receiver 204, input/output 206 and radio 208.
Wireless terminal 104a also comprises ~nt~nn~ 210, which is commllnic~tively coupled to radio 208 so as to facilitate the tr~ncmicsion and reception of signals to and from a base station. Directional receiver 204 comprises, for example, a helical antenna.
o The operation of wireless terminal 104a is as follows. A user points directional receiver 204 at a beacon to receive the electromagnetic carrier radiated by the beacon.
Directional receiver 204 recovers the identifying signal from the electromagnetic carrier and provides the identifying signal to processor 202, in well-known fashion. Processor 202 then provides the identifying signal to radio 208, which uses the identifying signal, in s well-known fashion, to initiate a call, via telecommunications system 100, to the co"""llnic~tion terminal associated with the identifying address.
For example, when an embodlment receives an identifying signal and tr~ncmic.civedata, which might be the serial number of the beacon, the embodiment could initiate the call based on the identifying signal, and, when the call is established, send the serial number to the called comm~lnic~tion terminal. Alternatively, the embodiment could concatenate the tr~ncmi.scive data to the identifying signal and transmit the tr~ncmiccive data as part of the call establishment process. In such case, the telecommllnications infrastructure would receive and process the tr~n.cmic.cive data.
FIG. 3 depicts an elevational view of an illustrative embodiment of the invention.
Beacon 102b includes a base 302 housing electronic circuitry for implementing embodiments of the invention. Beacon 102b also includes tr~ncmiccion housing 202 that houses a tr~ncmiccion element. According to an embodiment of the invention, the tr~ncmicsion element comprises an antenn~ or light emitting diode that radiates or emits an electromagnetic carrier in a wide range of angles (e.g., omnidirectionally). For example, as represented by angle a in FIG. 3, the antenna radiates an electromagnetic carrier that is substantially normal to the surface of ~ntPnn~ housing 304. In addition, as represented by angle ~ in FIG. 4, the ~ntçnn~ radiates the electrom~gnçtic carrier in all directions 360 5 about its base.
Beacon 102b can be mounted to exicting structures in many different ways. For example, beacon 102b can include a weighted base so that the beacon can be simply placed on the ground or on a pedestal. In the alternative, beacon 102b can include a suction cup or magnetic base pçrmittin~ it to be mounted, e.g., to an automobile or other o vehicle. Of course, various other mounting devices can be used, depending on a user's particular needs. In addition, as ~lescribed more fully below, beacon 102b can be made integral with the communication termin~l itself.
FIGs. 5 through 7 illustrate additional exemplary embodiments of the invention for use with telecomml-ni~ations system 100 of FIG. 1. The exemplary embotlimPnt~
5 advantageously combine conventional advertising or informational signs with a beacon to assist users of wireless terminals to initiate a call to, for example, a commllnication terminal associated with an advertiser.
FIG. S illustrates an embodiment that includes billboard 500 and an associated beacon 102c. Billboard 500 may be disposed adjacent to a highway or street as is well 20 known in the art. Billboard 500 displays, for example, an advertisement for a hotel or other establishment.
Beacon 102c radiates an electromagnetic carrier that is modulated with an ide.,lifying signal for a communication termin~l associated with the advertiser.Advantageously, beacon 102c may be disposed on billboard 500 as shown. .AltPrn~tively, 25 beacon 102c can be placed in another location such that a wireless terminal receives the electromagnetic carrier from beacon 102c when directed at beacon 102c. In operation, a user of a wireless terminal communicates with an advertiser by receiving the identifying ~o signal from beacon 102c and using the signal to initiate a call to a communication terminal associated with the advertiser.
FIG. 6 illustrates another exemplary embodiment of the invention. Beacons 102d, 102e, and 102f are mounted on a sign 600 so as to broadcast multiple identifying signals.
s The identifying signals may identify di~ nl entities or advertisers. For example, sign 600 can provide frequently used, emer~l~;y, or informational telephone numbers such as police dep~l,nent, fire dep~ll~Rnt or information. Sign 600 can be mounted in or on a building, adjacent to a highway or in other public or private places that are acces~ihle to large volumes of people. Alternatively, as shown in FIG. 7, beacon 102g can radiate an o electromagnetic carrier modulated with the identifying signal for each advertiser that advertises on sign 700. In this embodiment, the electromagnetic carrier can also radiate user data (e.g., alphanumeric tags "Police", "Fire", and "Information") that is displayed to the user of a wireless terrnin~l to select the applopliate identifying signal for use in initiating a call. In operation, the wireless termin~l user points the directional receiver of 5 the wireless terminal at beacon 102g and receives the three identifying signals and the associated user data. The wireless terminal displays the user data to the user. The user selects the identifying signal based on the displayed user data and initiates a call to a comrnunication termin~l associated with the appropliate advertiser.
The embo-lim~qnt~ of FIG. 5 through 7 can be used in a wide range of applications.
20 For example, many airports, bus and train stations have courtesy telephones arranged a~ljanent to a sign advertising local hotels, restaurants and car rental agencies. Such courtesy telephones can be replaced by, or supplemented with, one or more beacons mounted on or near the sign that transmit identifying signals for the advertisers. Travelers with wireless terminals can contact a desired advertiser by pointing the directional receiver 2s at the approp,iate beacon and initi~ting a call. Further, a beacon may be placed on a sign at a drive-thru restaurant. When a patron reaches the sign to place an order, the patron can initiate a call with a wireless terminal. Thus, the patron avoids the frustration of comm-lnic~tin~ over the typical intercom systems used by these establi~hmlont~.

Il In some circl-m~t~n~es, there can be several beacons in close proximity to one another. Advantageously, wireless terminal 104a is able to distinguish between the electrom~gnçtic carriers radiated by those beacons, and the user is able to select which identifying signal radio 208 uses by pointing directional receiver 204 at the beacon whose 5 electrom~gn~tic carrier the user desires to receive. Directional receiver 204 advantageously compri~es a highly-directional ~nt~nn~ with a conic field-of-view (i.e., beamwidth) of between 2 and 5. From a functional ~.s~;~ive, the directional nature of directional receiver 204 allows a user to ~ rrimin~tç ~t~n signals radiated from a plurality of proximate beacons by pointing directional receiver 204 at the desired beacon.
For example, as shown in FIG. 14, beacons 902a, 902b, and 902c are in close proximity and each radiate the identifying address of a different communication termin~l Beacons 902a, 902b, and 902c can be placed in close proximity, such as on a billboard or sign advertising more than one service or org~ni7~tion. In other cases, beacons 902a, 902b, and 902c can be quite distant from one another, but because of perspective merely s appear to be close. For example, the three beacons could be on three successive automobiles on a highway and the user is in a fourth automobile behind them. Thedirectional nature of directional receiver 204 thus enables the user to call the occupants of whichever of the three automobiles he or she desires.
Directional receiver 204 may interface with processor 202 in a variety of ways.
For example, direction~l receiver 202 may be fabricated, and rigidly fixed, within the structural housing of wireless terminal 104a. In such case, the interface from directional receiver to processor 202 can comprise a wire or a conductor on a printed circuit board.
According to this arrangement, the user effectively points directional receiver 204 by holding and pointing the housing of wireless terminal 104a.
2s Alternatively, directional receiver 204 can be housed in a separate housing that is comml-nic~tively coupled to processor 202 by a wire, as shown in FIG. 8. Directional receiver 204a comprises directional ~ntçnn~ 302 that is coupled to receiver 304. Wire 306 couples receiver 304 to processor 202 of FIG. 2b. Wire 306 may comprise a wire, an .

optical fiber, a conductor on a printed circuit board or other connection between receiver 304 and processor 202. In operation, directional ~ntçnn~ 302 receives an electromagnetic carrier from a beacon and transmits the signal to processor 202 via receiver 304 and wire 306.
s In some circl-mst~nres, a wired interface be~ directional receiver 204 and processor 202 can be cumbersome. For example, wire 306 of FIG. 8 can tangle easily.
Thus, directional receiver 204 may ~lt~rn~tively intçrf~ce with processor 202 via a wireless connection.
FIG. 9 is a block diagram of an embodiment of a directional receiver that illustrates l o a wireless interface with processor 202. Directional receiver 204b advantageously includes a removable, hand-held wand 402 that comm~lnic~t~s with co~ ,lunication circuit 404, which is inside the housing of the wireless terminal with processor 202.
Wand 402 comprises directional ~nt~nn~ 406 that is coupled to transmit ~ntçnn~
408 through transceiver 410. Comm--nication circuit 404 comprises antenna 412 that is lS coupled to receiver 414. In operation, a user positions wand 402 so that directional antenna 406 is pointed at a beacon to receive the electromagnetic carrier. Transceiver 410 transmits the electromagnetic carrier to communication circuit 404, in well-known fashion.
Communication circuit 404 receives the signal and provides it to processor 202. It is preferred that antenna 412 be omni-directional so that the relative spatial relationship and orientation between wand 402 and communi~;~tion circuit 404 is unimportant to the operation of the embodiment.
FIG.10 is a block diagram of input/output 206 for wireless terminal 104a of FIG.2b. Input/output 206a comprises: display 508, keypad 502, trigger 510, audio speaker 504, microphone 506 and beacon 512. Display 508, keypad 502, microphone 506 and 2s audio speaker 504 are all made and used in well-known fashion.
As mentioned above, a beacon can transmit user data (e.g., the name of the party~
associated with the identifying signal, a short advertisement, etc.) to be output to the user.
This user data can be conveyed to the user visually via display 508 or audibly through audio speaker 504. Processor 202 is advantageously capable of converting user data to speech, in well-known fashion.
It may not be desirable for wireless termin~l 104a to initiate a call every time its directional receiver fortuitously receives an identifying signal from a beacon. Therefore, it s may be advantageous for the user to be able to control when the embodiment initi~t~s a call based on a received identifying signal. For this reason, there exists trigger 510.
When trigger 510 is asserted by a user, processor 202 advantageously initiates acall using the ~;u~ ltly received or the next received identirying signal. Trigger 510 may comprise a mechanical trigger such as a depressable button that is disposed on the wireless terminal or on the removable directional receiver or wand. Alternatively, the embodiment can comprise voice recognition capability so that trigger 510 can be asserted by voice command of the user. Furthermore, inputloutput 206a advantageously provides audio, video and/or tactile feedback to the user to indicate when an identifying signal has been capt~lcd and a call initi~t~ based on the identifying signal.
ls Input/output 206a may additionally comprise beacon 512 for tr~n~mitting an identifying signal associated the embodiment. This would enable a user of another embodiment to call the user of the illustrative embodiment.
For example, FIG. 11 depicts an embodiment of the invention that includes both directional receiver 204c and beacon 512a. Wireless termin~l 104b further advantageously comprises a housing 602 that holds processor 202 (not shown), radio 208 (not shown), antenna 210a, audio speaker 504a, display 508a, keypad 502a, microphone 506a andtrigger 510a. Beacon 512a is advantageously structurally attached to housing 602.
To reduce the chance that the electromagnetic carrier transmitted by beacon 512awill inlt;lÇ~ with the electromagnetic carrier that the user desires to capture, wireless 2s terrninal 104b may t~ po,~ily disable beacon 5 12a from r~ ting when trigger 510a is depressed.
Although in this embodiment directional antenna 204c is either tempoldlily or perm~n~r~tly attached to housing 602, it is advantageously affixed in such a manner that a ` 2191805 user of the embodiment can effectively aim or point directional antenna 204c by m~nu~lly holding and pointing with wireless terminal 104b at a beacon. In other embo-lim~ntc of the invention, a directional receiver may be contained in a separate housing. For example, wireless terminal 104c of FIG. 12 comprises wand 402b that is wirelessly coupled to s wireless terminal 104c. Further, as shown in FIG. 13, wand 402c is structurally coupled to a pair of glasses 802 and wirelessly coupled to wireless tçrmin~l 104d.
When a beacon is structurally attached to the co,m"unications terminal whose identifying signal it radiates, the beacon is said to be a "neighbor" beacon. When a beacon is not structurally attached to the cornmunication terminal whose identifying signal it lo radiates, the beacon is said to be a "proxy" beacon. It will be clear to those skilled in the art that there are applications in which it is preferred that one or more neighbor beacons be employed, applications in which it is preferred that one or more proxy beacons be employed, and applications where both neighbor and proxy beacons are employed.
To facilitate privacy and restrict the number of users who can receive information lS radiated by a beacon, the user data, tr~ncmiccive data and/or identifying signal radiated by a beacon may be encrypted, in well-known fashion. In such cases, processor 202 must be capable of decrypting the encrypted information. Processor 202 may be given the cryptographic key via a keypad or penpad, or via telecommunications system 100.
Although the invention has been described with emphasis on particular embodiments for providing an identifying address to comml-nication terminals, it should be understood that the Figures are for illustration of exemplary embodiments of the invention only and should not be taken as limitations or thought to be the only means of carrying out the invention. For example, the invention is not limited to cellular networks, but rather may be employed into numerous communication systems, such as a Personal 2s Communication System or into communication systems ~ltili7ing Personal and/or Terminal Mobility managers. Further, it is contemplated that many changes and modifications may be made to the invention without departing from the spirit and scope of the invention as disclosed above.

Claims (9)

Claims

1. A telecommunications system (100) comprising:
at least one beacon (102) for radiating an electromagnetic carrier modulated with an identifying signal associated with a first communications said beacon comprising a memory (206) for operably storing said identifying signal, a controller (208) responsive to said memory for generating said electromagnetic carrier modulated with said identifying signal, and a transmission element (210) responsive to said controller for omnidirectionally transmitting said electromagnetic carrier; and at least one second communications terminal (104) capable of initiating a telecommunications call to said first communications terminal, said second communications terminal comprising a directional receiver (204) for receiving said electromagnetic carrier transmitted from said beacon, a processor (202) responsive to said directional receiver for recovering said identifying signal, and a radio (208) responsive to said processor that is capable of initiating a call to said first communications terminal based on said identifying signal.

2. The system of claim 1, wherein said second communications terminal further comprises a wireless terminal.

3. The system of claim 1, wherein said second communications terminal further comprises a trigger operatively coupled to said processor, said trigger being operable to effect initiation of said call.

4. The system of claim 1, wherein said radio is capable of initiating a telecommunications call of the type selected from the group consisting of voice, video, data or multimedia.

5. The system of claim 1, wherein said beacon further comprises a transceiver coupled to the memory that receives signals for modifying the identifying address stored in the memory.

6. The system of claim 1, wherein said transmission element comprises a helical antenna.

7. The system of claim 1, wherein said identifying signal includes at least one telephone number.

8. The system of claim 1, wherein said electromagnetic carrier further comprisesuser data and transmissive data modulated thereon, and wherein said processor is further operable to recover said transmissive data and said user data from said electromagnetic carrier and to transmit at least a portion of said transmissive data and said user data as part of said call.

9. The system of claim 1, wherein said controller comprises a transmitter that generates the signal transmitted by the transmission element.