Abstract:
A method of providing dispatch mode calling in a code division multiple access (CDMA) wireless network ( 10 ). The method includes the steps of defining at least one dispatch mode talk-group, receiving a dispatch mode call request from an originating mobile phone ( 48 ) in the talk-group, determining location information for destination mobile phones ( 50, 52, 54, 56 ) in the talk-group, and encoding and sending the voice packets to the destination phones, along with information to enable the destination phones to decipher the encoded voice packets.

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates to wireless telecommunications, and in particular, to a method of providing dispatch mode calling in a code division multiple access wireless network. 
     2. Description of the Prior Art 
     “Dispatch mode” is a radio communications technique where one radio communicates to many other radios using short bursts of communications. Many groups such as taxi drivers and police officers desire to communicate with dispatch mode radio devices because it allows them to speak with a number of other people at the same time without initiating a plurality of separate phone calls. Until recently, dispatch mode services were only available in two-way radio systems such as walkie talkies. Although these radio systems work effectively when all of the users are located close together, they become ineffective once the users travel beyond the range of the radio transceivers. 
     Nextel has recently begun offering dispatch mode operations in its enhanced specialized mobile radio (ESMR) systems. ESMR can be deployed on a cellular network and, therefore, supports network features that enable users to operate in dispatch mode over greater distances. ESMR systems use time division multiple access (TDMA) technology which allocates a discrete amount of frequency band width to each user of the system to permit many simultaneous conversations. Each caller is allowed to transmit in predetermined time slots so that channelization of users in the same band is achieved through separation in time. Unfortunately, the capacity of these networks is limited by the number of available time slots. TDMA networks also suffer from poor call clarity, “hard” call hand-offs and minimal call security. 
     Companies such as Sprint PCS have recently begun offering wireless communication services using code division multiple access (CDMA) techniques. CDMA is a digital spread-spectrum modulation technique which digitizes wireless conversations and tags them with special codes. The digitized data is spread across the frequency band in a pseudo random pattern. Receiving mobile phones are instructed to decipher only the data corresponding to particular codes to reconstruct the signal. CDMA networks offer advantages over TDMA networks including increased network capacity, fewer dropped calls because of better hand-off methods, improved voice clarity, improved privacy and transmission security, and enhanced services such as text messaging and data transmissions. However, until now, CDMA wireless networks have not included dispatch mode calling capabilities. 
     SUMMARY OF THE INVENTION 
     The present invention solves the above-described problems and provides a distinct advance in the art of wireless telecommunications networks. More particularly, the present invention provides a method of providing dispatch mode calling in a CDMA wireless network. 
     The method of the present invention is implemented by first defining at least one talk-group consisting of a plurality of mobile phones in a CDMA network operated by users who wish to communicate with each other in a dispatch mode. To initiate a dispatch mode call, an originating phone sends a dispatch mode call request to the network. The dispatch mode call request is validated, then the location of the destination mobile phones in the talk-group is determined. Voice channels are then assigned to the members of the talk-group and a group code or mask is sent to each destination phone that enables the phones to demodulate or decode communications from the originating phone. Voice packets are received from the originating mobile phone, encoded, and sent to the destination phones. The destination mobile phones then decipher the encoded voice packets with the received mask. 
     The present invention permits dispatch mode calling between a plurality of users in a talk-group all located within the same sector of a telecommunications cell without adversely affecting the capacity of the cell. Specifically, the method assigns a first Walsh code to the forward traffic channel for the originating mobile phone that all mobiles listen to if they are located in the same sector, and a second Walsh code to the forward traffic channel for all other destination mobile phones that are located in a different sector. Thus, a dispatch mode call between mobile phones in the same sector of a telecommunications cell utilizes the same network capacity as a conventional wireless call between only two mobile phones. 
     The method of the present invention also provides dispatch mode calling for members of a talk-group even when the members are located in more than one telecommunications cell. This is achieved by replicating the encoded voice packets and routing a copy of the voice packets to each base station serving a cell in which any destination mobile phone is located. For example, if destination phones are located in three different telecommunications cells, the present invention includes the step of replicating the encoded voice packets and routing the voice packets to each of the three base stations serving the three cells. 
    
    
     BRIEF DESCRIPTION OF THE DRAWING FIGURES 
     A preferred embodiment of the present invention is described in detail below with reference to the attached drawing figures, wherein: 
     FIG. 1 is a schematic diagram broadly illustrating a code division multiple access wireless network configured to support dispatch mode calling in accordance with a preferred embodiment of the present invention. 
     FIG. 2 is a schematic diagram of one base station of the wireless network. 
     FIG. 3 is a schematic diagram of a dispatch mode controller constructed in accordance with a preferred embodiment of the present invention. 
     FIG. 4 is a flow diagram generally illustrating the steps performed by the wireless network when establishing a dispatch mode call. 
     FIG. 5 is a schematic diagram illustrating the forward traffic channel structure for dispatch mode calling in the present invention. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     System Architecture 
     Turning now to the drawing figures, an example of a wireless telecommunications network  10  that may be used to implement a preferred embodiment of the present invention is illustrated. The illustrated architecture is shown for purposes of disclosing a preferred embodiment and can be modified as a matter of design choice. The wireless network is preferably a code division multiple access (CDMA) PCS wireless intelligent network such as the PCS network owned and operated by Sprint PCS. As is well known in the art, the wireless network is coupled with a public switched telephone network (PSTN)  12 . The PSTN refers to the entire local, long distance, and international landline phone system used in the United States, which includes well known components such as central office local exchange carriers (LECs) and interexchange carriers (IXCs). 
     The wireless network  10  broadly includes a plurality of base stations (BTSs)  14 ,  16 ,  18 , a digital access and cross-connect system (DACS)  20 , a base station controller (BSC)  22 , a mobile switching center (MSC)  24 , a signal transfer point (STP)  26 , a wireless intelligent network service control point (WIN SCP)  28 , and a home location register (HLR)  30 , all interconnected by signaling data links and trunk circuits as described below. In accordance with the present invention, the wireless network also includes a dispatch mode controller (DMC)  32  operable to provide dispatch mode calling to mobile phones served by the network. 
     The BTSs  14 ,  16 ,  18 , which are well known in the art, provide wireless communications to and from mobile phones and other wireless devices. FIG. 2 illustrates one BTS  14  in more detail. The BTS includes a plurality of transceivers  34 ,  36 ,  38  coupled with one or more antennas that together provide wireless communications within a telecommunications cell  40 , which is preferably subdivided into three sectors  42 ,  44 ,  46 . The BTS serves a plurality of mobile stations  48 ,  50 ,  52 ,  54 ,  56  such as PCS/cellular phones located in the cell. The cell is preferably part of a CDMA PCS telecommunications network such as the Sprint PCS network described above. The preferred BTSs are operable to control transmission and reception of CDMA PCS traffic independently in the three sectors using selected ones of a defined set of codes for each sector. The codes may include, for example, Walsh codes. An example of a BTS that may be used with the present invention is the Nortel CDMA Outdoor 1900 MHZ base station. Those skilled in the art will appreciate that the wireless network may include numerous BTSs positioned in telecommunications cells throughout the country. 
     Returning to FIG. 1, the DACS  20  is coupled with the BTSs  14 ,  16 ,  18  with signaling data links and trunk circuits  58 ,  59 ,  60  and is operable for routing and switching control messages between the BTSs and the other components in the wireless network. The BSC  22  is coupled with the DACS with signaling data links and trunk circuits  61  and is operable to control operation of the DACS and the BTSs  14 ,  16 ,  18 . The BSC is basically a high-capacity switch that provides total overview and control of wireless functions supported by the network such as call handoff control, cell configuration management, and BTS and mobile phone power level management. The BSC multiplexes signals from the BTSs into transmission signals that are sent to the MSC  24 . The BSC also routes network signals and calls from other components of the wireless network to the appropriate BTS for transmission to the mobile stations. 
     The MSC  24  is coupled with the BSC  22  and other base station controllers with signaling data links and trunk circuits  62  and is operable to coordinate the establishment of calls to and from the mobile stations  48 - 56  and to handle transmission facilities management, mobility management, and call processing. The MSC is also connected with the PSTN  12  by signaling data links and trunk circuits  64  to provide switching between the wireless network and the PSTN. 
     The MSC  24  either includes an integrated visitor location register (VLR)  66  or is coupled with a stand-alone VLR. The VLR includes a database that contains information relating to visiting mobile phones that are roaming outside of their home service area. When a mobile phone is roaming in a visiting service area, the local provider in the visiting service area queries the HLR  30  through the STP  26  using Signaling System #7 (SS7) or other signaling to retrieve information needed to verify the legitimacy of the mobile phone and to obtain a profile of the features associated with the mobile phone. The HLR responds to the query by transferring the necessary data to the VLR. This information is maintained in the VLR of the local provider as long as the roaming mobile phone remains active within that coverage area. The HLR also updates its own database to indicate the current location of the roaming mobile phone so that it can divert calls to the phone through the local provider in the visiting service area. The querying process in the preferred wireless network is accomplished via SS 7  links using the STP and SCP as described below. 
     The STP  26  is connected between the MSC  24  and the WIN SCP  28  by signaling data links  68  and  70  and is operable to route signaling messages therebetween. STPs are well known in the art with an example being the DSC Megahub. 
     The WIN SCP  28 , which is well known in the art, preferably uses TCAP protocols to perform transaction processing for wireless calls. However, other signaling systems or means to exchange messages are equally applicable to the present invention. The WIN SCP is coupled with the STP  26  to exchange signaling messages with the MSC  24  and other mobile switching centers. The WIN SCP also includes a plurality of databases for providing intelligence and certain enhanced services to the wireless network as described herein. 
     The HLR  30  may be a database residing on the WIN SCP  28  or may be a stand-alone database servicing several SCPs. In either case, the HLR includes a database containing subscriber data and information used to identify a subscriber of the wireless network and subscriber data relating to features and services available to the subscriber. The HLR, which represents the “home” database for subscribers, may, for example, contain a record for each home subscriber that includes location information, subscriber status, subscribed features, and directory numbers. The HLR is used in conjunction with the VLR  66  as described above to support mobility management features to which the user has subscribed when that user is roaming outside of his home area. 
     As is well known in the art, the MSC  24 , STP  26 , WIN SCP  28 , HLR  30 , and VLR  66  all communicate via out of band signaling, typically using SS7 or TCP/IP protocols to facilitate the routing of calls through the wireless network. The signaling allows the network elements to exchange information to more quickly and efficiently route calls over the network. 
     In accordance with the present invention, the dispatch mode controller (DMC)  32  is operatively coupled with the other components of the wireless network  10  to provide dispatch mode calling capabilities. As illustrated in FIG. 3, the DMC broadly includes a front end processor (FEP)  72 , a metro packet switch (MPS)  74 , and a dispatch application processor (DAP)  76 . 
     The FEP  72  serves as an interface for coupling the DMC  32  with other components in the wireless network. In preferred forms, the FEP is coupled with the MSC  24  with data links and trunk circuits  78  to provide signaling and call routing therebetween. The FEP is also coupled with the STP  26  by signaling data links  80  to provide control signaling therebetween and with the PSTN  12  by data links and trunk circuits  81  to provide signaling and call routing therebetween. 
     The MPS  74  is coupled with the FEP  72  and includes a digital packet switch  82  and one or more packet duplicators  84 . The MPS is operable to receive voice packets from the BTSs  14 ,  16 ,  18  via the MSC  24  to transport voice packets to the BTSs, and to route control information between the DAP  76  and the BTSs during a dispatch call. 
     The DAP  76  is coupled with the FEP  72  and includes a processor  86  and at least one database  88 . The DAP maintains and tracks subscriber provisioning and mobility information for dispatch mode calls and is responsible for the overall coordination and control of dispatch mode services. 
     Dispatch Mode Operation 
     Setup 
     To permit dispatch mode calling in the above-described wireless network  10 , an operator must first define or create “talk-groups” of mobile phone users who wish to at least occasionally communicate in dispatch mode. For example, one talk-group may consist of the mobile phones  48 ,  50 ,  52 ,  54 ,  56  illustrated in FIG.  2 . Subsets of these mobile phones and/or additional phones may be part of another talk-group. This way, a user of any one of the mobile phones may be a part of a number of different talk-groups. 
     A talk group may include only two mobile phones or many phones. The mobile phones in a talk group may all be positioned within a “local dispatch location area” serviced by a single BTS, a “selected service area” served by several base stations connected to the same MSC, or a “Wide area” served by base stations positioned throughout the country serviced by a plurality of different MSCs. 
     Once the talk-groups have been defined, information relating thereto such as the identification of each talk-group and an identification number for each phone in a talk-group is stored in the database  88  of the DAP  76 . For example, a lookup table indicating that talk-group number  1  consists of the mobile phones  48 ,  50 ,  52 ,  54 ,  56  illustrated in FIG. 2, talk-group number  2  consists of other mobile phones, etc. is stored in the database. The mobile identification number (MIN) for each mobile phone in a talk-group is also stored in the database or in an external database that can be accessed by the DAP. 
     The mobile phones  48 ,  50 ,  52 ,  54 ,  56  must also be configured to permit dispatch mode calling. Specifically, each phone must be configured to allow a user to indicate that he or she wishes to initiate a dispatch mode call rather than a conventional call. The phones may be equipped with dedicated dispatch mode keys for this purpose or may be programmed to recognize an entered code that triggers a dispatch mode call. Each mobile phone is also preferably programmed to include a menu that allows a user to select which talk-group he or she wishes to communicate with. For example, if one of the mobile phones is a part of three different talk-groups, the mobile phone must be programmed to allow the user to select with which talk-group he or she wishes to communicate. 
     Operation 
     Before describing the dispatch mode operation of the network  10 , it is helpful to understand a few principles about the normal, non-dispatch mode operation of the network. To send a call to one of the mobile phones illustrated in FIG. 2, the BTS  14  transmits in the cell a long code to which the mobile identification number (MIN) of the phone is attached. Although all the phones in the cell receive the transmission, only the phone identified by the transmitted MIN can decode it. 
     As generally illustrated in FIG. 5, in the dispatch mode operation of the network, a group code that identifies a group of mobile phones is substituted forthe MIN of a specific phone in the forward channel. This permits every phone in the group to decode a dispatch mode transmission. 
     In more detail, a preferred embodiment of the dispatch mode operation of the present invention can be best understood with reference to FIG. 2, which illustrates a talk-group of mobile phones  48 ,  50 ,  52 ,  54 ,  56  all positioned within a “local dispatch location area” such as a company campus served by a single BTS  14 . Assume for this example that the mobile phone  48  (referred to herein as the “originating mobile phone”) wishes to initiate a dispatch call to the mobile phones  50 ,  52 ,  54 ,  56  (referred to herein as the “destination mobile phones”). FIG. 4 generally illustrates the steps in completing such a call. The user of the originating mobile phone initiates a dispatch call by selecting a talk-group and then striking a dispatch mode call request key on his or her phone or entering a dispatch request code as described above. The mobile phone responds by transmitting a dispatch mode call request including an identification of the requested talkgroup to the originating BTS via a control channel as generally depicted in step  400 . The BTS determines if it has available capacity to handle the call and ques the call if it does not. 
     If the BTS  14  has capacity available to handle the call, it routes the call request and talk-group identifier to the DACS  20 . The DACS connects the request to the MSC  24 , which recognizes that the call request is for a dispatch mode call and forwards the request to the DMC  32  as depicted in step  402 . If the call request was not for a dispatch mode call, the MSC would handle the call request in a conventional manner. 
     Once the DMC  32  receives the dispatch mode call request, it validates the request and coordinates the dispatch mode call. Specifically, the processor  86  of the DAP  76  first accesses the database  88  to identify the members of the requested talk-group as depicted in step  404 . The DAP then determines the status and current location of each destination mobile phone in the talk-group by sending a status and location query to the HLR  30  via the STP  26 . The HLR responds with current cell and sector information for each mobile phone as depicted in steps  406  and  408 . 
     If at least one of the destination mobile phones in the talk-group is available to receive the dispatch call, the DAP  76  signals the BTS  14  via the MSC  24  to provide voice channels to the originating mobile phone  48  and the destination phones  50 ,  52 ,  54 ,  56  that are available as depicted in step  410 . Destination phones that are not initially available may be added to a dispatch call as they become available as they will be able to decode the signal. 
     While setting up voice channels, the DMC  32  instructs the BTS  14  to assign a first Walsh code to the forward traffic channel for the originating mobile phone  48  and a second Walsh code to the forward traffic channel for all destination mobile phones in one sector of the cell. If the destination mobile phones are in more than one sector as illustrated in FIG. 2, the DMC and BTS assign a separate Walsh code for each sector in which a destination phone is located. 
     During call setup, the DMC  32  and BTS also send each active member of a talk-group a group code that serves as a mask to allow all of the mobile phones in the group to demodulate or decode the dispatch mode call. This enables all members of a talk-group to participate in a dispatch mode call. 
     When the user of the originating mobile phone  48  begins to talk, the phone sends digitized voice packets to the BTS  14 , which forwards them to the DMC  32  via the MSC  24  for processing. The packet switch  82  and packet duplicator  84  replicate the voice packets and distribute a copy to each cell in which one of the destination mobile phones is currently located as depicted in steps  412  and  414 . In the example illustrated in FIG. 2, only one copy is required because all of the destination phones are in the same cell. However, if the DAP  76  determines that destination phones are in three different cells, the packet switch and packet duplicator make three copies of the voice packets and send a copy to the BTS serving each cell. 
     Similarly, the DAP  76  may determine that one of the destination mobile phones is currently roaming outside of the home coverage area of the MSC  24 . Then, the DMC  32  would route the voice packets to the PSTN  12  for routing to the MSC and BTS in which the destination mobile phone in the talk group is currently roaming. 
     Once the BTS or BTSs receive the copied voice packets from the DMC  32 , they transmit the voice packets in the cell or cells to the mobile phones in a conventional manner as depicted in step  416 . Because all of the phones in a talk-group have been provided with the mask necessary to demodulate the transmitted voice packets, each destination mobile phone can decode the voice packets so that all the destination mobile phones can communicate with the originating mobile phone. 
     To regulate the power of mobile phones in a talk-group that are in the same cell, the BTS uses the closed loop power control to set the transmitted power of the mobile group that is usually in close by locations to an average value that will correspond to an acceptable FER value. 
     In addition to voice communications between members of a talk-group, the DMC  32  may also provide for the sending of call alerts, emergency calls, and status inquiries between members of a talk-group. 
     Although the invention has been described with reference to the preferred embodiment illustrated in the attached drawing figures, it is noted that equivalents may be employed and substitutions made herein without departing from the scope of the invention as recited in the claims.