WO2013142103A1 - System and method for efficient operation of cellular communication networks - Google Patents

System and method for efficient operation of cellular communication networks Download PDF

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Publication number
WO2013142103A1
WO2013142103A1 PCT/US2013/030001 US2013030001W WO2013142103A1 WO 2013142103 A1 WO2013142103 A1 WO 2013142103A1 US 2013030001 W US2013030001 W US 2013030001W WO 2013142103 A1 WO2013142103 A1 WO 2013142103A1
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WO
WIPO (PCT)
Prior art keywords
network
gps location
cell
data
record
Prior art date
Application number
PCT/US2013/030001
Other languages
French (fr)
Inventor
Tara Chand Singhal
Original Assignee
Tara Chand Singhal
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Priority claimed from US13/473,493 external-priority patent/US11889455B2/en
Application filed by Tara Chand Singhal filed Critical Tara Chand Singhal
Priority to CN201380015056.8A priority Critical patent/CN104205794B/en
Priority to CA2867664A priority patent/CA2867664A1/en
Priority to EP13764270.8A priority patent/EP2829052B1/en
Publication of WO2013142103A1 publication Critical patent/WO2013142103A1/en

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Classifications

    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W8/00Network data management
    • H04W8/02Processing of mobility data, e.g. registration information at HLR [Home Location Register] or VLR [Visitor Location Register]; Transfer of mobility data, e.g. between HLR, VLR or external networks
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W4/00Services specially adapted for wireless communication networks; Facilities therefor
    • H04W4/02Services making use of location information
    • H04W4/029Location-based management or tracking services
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W76/00Connection management
    • H04W76/50Connection management for emergency connections
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04BTRANSMISSION
    • H04B17/00Monitoring; Testing
    • H04B17/30Monitoring; Testing of propagation channels
    • H04B17/309Measuring or estimating channel quality parameters
    • H04B17/318Received signal strength
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W4/00Services specially adapted for wireless communication networks; Facilities therefor
    • H04W4/02Services making use of location information
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W4/00Services specially adapted for wireless communication networks; Facilities therefor
    • H04W4/90Services for handling of emergency or hazardous situations, e.g. earthquake and tsunami warning systems [ETWS]
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W64/00Locating users or terminals or network equipment for network management purposes, e.g. mobility management
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W68/00User notification, e.g. alerting and paging, for incoming communication, change of service or the like
    • H04W68/08User notification, e.g. alerting and paging, for incoming communication, change of service or the like using multi-step notification by increasing the notification area

Definitions

  • a system using GPS location of cell phone devices to improve the operation of cellular communication networks uses cell phone devices that use Registration-Request Signal transmission from the cell phone device to convey GPS location of the device to the wireless network.
  • Cellular communication networks operate with and have cell phone devices, sometimes called handsets, cell towers, base stations, mobile switching center (MSC), with access to home location record (HLR) database that maintain subscriber data including their present location by a geographic cell number.
  • the handsets communicate to the network via the cell towers on control and data channels.
  • Networks detect registration-request (R-R) signals on the control channel from the handset and record in the HLR database the presence of the handset in the cell the handset sent the R-R signal from.
  • R-R registration-request
  • the operation of cellular network depends on knowing the general location of the handset in a group of cells to page the handset in those contiguous cell areas and route a call to the given cell area from which the handset responds to the page. That general location of the handset in the HLR database requires the MSC to page a handset in multiple cells based on last known area.
  • Cellular networks rely on a technique known as triangulation based on signal strength received from the handset at a minimum of three different cell towers. The measured received signal strength is used for computing a location of the handset in the cell space using a triangulation algorithm. This approach of triangulation to determine the physical location of the handset within a cell space is used for both battery management in the handset and also used for 91 1 emergency calls to provide a location of the handset to the emergency responders as required by a 91 1 federal mandate.
  • the telephone company In the prior art landline based telephone system, the telephone company always knew of the physical location of a call originated on a landline telephone device. With the advent of the cellular wireless network and the cell phone devices that operate with such a wireless network that is not possible as the cell phone device is mobile and may be in any location in a geographic area.
  • the embodiments described herein enable the wireless networks to maintain a precise location of the cell phone devices at all the times. Such embodiments are useful for many purposes, not the least of which is to route 91 1 emergency calls originating via the mobile cell phone device.
  • the other purpose is to provide an efficient operation of the wireless cellular network then that has been possible in the prior art cellular telephone networks.
  • geographic space over which cellular service is provided is partitioned in to a large number of geographic cells.
  • Each geographic cell is about a few square miles and is covered by multiple cellular tower antennas. Coverage of a cell area by three towers is preferred, as the three cell towers by measuring the relative strength of the cell phone transmission and by using triangulation can determine the location of the cell phone within the cell space.
  • This location of the cell phone within the cell itself is not required for the cellular telephone network operation itself.
  • the cellular network may use this location information of the cell phone within the geographic cell for purposes other than cellular network operation.
  • One such purpose is to support a federal 91 1 mandate.
  • Other such purpose is to reduce the transmission power of the cell phone based on distance to the nearest tower to minimize battery usage and thus enhance battery life.
  • the cell phones are mobile and based on the cell phone owner's life style and vocation a cell phone may move within a cell space, not move at all, or move rapidly across many cells such as when the cell phone owner is in a vehicle in motion or is in a flight. Thus the cell phones may therefore either not change their cell location or change their cell location slowly, or change rapidly and unpredictably.
  • the cellular network it is necessary for the cellular network to know in which specific geographic cell the cell phone is physically located at any given time.
  • cell phones have been designed to periodically broadcast an identity signal, called Registration-Request Signal (RRS) that is used by the cellular network to determine and then save the geographic cell location of a wireless mobile cell phone in a network database.
  • RTS Registration-Request Signal
  • the network database is maintained by the cellular carrier and is referenced to and used for routing incoming calls to the specific cell where the cell phone is located.
  • the Registration-Request Signal (RRS) is broadcast by the cell phone every few seconds.
  • the RRS should not be confused with the roaming and roaming signal which uses the same Registration-Request Signal in a cell phone to operate in a cellular carrier area that is not covered by the home carrier with which the cell phone owner has contracted for the cell telephone service.
  • the location of the cell phone in a specific cell that is maintained in the network database is used to route incoming calls to the geographic cell where the cell phone is located. These incoming calls may originate in any part of the landline and cellular network nationally or globally.
  • the cellular network uses these Registration-Request Signals from the devices to record and maintain in a database the current cell location of the device.
  • the database is used to determine the current cell location of the device so that the incoming calls are routed to the specific cell where the device is located based on the Registration-Request Signals being transmitted from the device to the network.
  • the first of these aspects minimizes or suppresses the transmission of the R-R Signal from the cell phone device when the cell phone has not moved more than 100 feet from an immediate prior location.
  • the second aspect is that the R-R Signal transmission embeds the GPS location data of the cell phone device.
  • Both of these aspects are capable of independent operation of each other.
  • First of these aspects has been described earlier in another pending application of the applicant as a means to economize on the battery life of the cell phone device.
  • Both of these aspects of technology working together provide for a more efficient cellular network operation as described in the embodiments herein.
  • the first as well as the second of these aspects and their benefits are described in detail in this application.
  • the embodiments described herein provide a Registration-Request Signal Transmission Management (RRSTM) logic that would manage and optimize the Registration-Request Signal transmissions from the cell phone device based on the individual user behavior of using a cell phone. That is, determine when the cell phone has moved and how much it has moved relative to a geographic cell and use that information to either not suppress prior art Registration-Request Signal transmissions or suppress such prior art Registration-Request Signal transmissions. Dynamically adjusting the rate of Registration-Request Signal transmission that is made possible by the RRSTM logic does not affect the cellular operation of the cell phone as any use of the cell phone is not affected by dynamically adjusting the Registration-Request Signal transmission as had been described above.
  • control channels and data channels are used for communicating and exchanging control data such as RR signal and to communicate voice/data channels to be used for a given voice/data connection.
  • control channel for RR signal does not affect the operation of the cell phone in sending and receiving voice and data transmissions.
  • the R-R logic in handsets is modified to include a current GPS location data of the cell phone device in the R-R record.
  • the wireless network from the received R-R record retrieves the GPS location data of the cell phone devices and saves in the HLR database.
  • the HLR database is able to maintain such location data in the HLR database.
  • Maintaining such GPS location data in the HLR database provides multiple benefits for improving the operation of the wireless networks.
  • One of these benefits is that of accurate paging of the cell phones for routing incoming calls.
  • Another of these benefits is to be able to provide for wireless network originated 91 1 calls, the seamless location of the cell phone device to emergency responders.
  • Yet another benefit may also be to calibrate the device's signal transmission strength in lieu of using triangulation algorithms that are used in prior art.
  • Figures 1 is a block diagram that illustrates the features of GPS location data in the operation of the cellular communication network
  • Figure 2A is a block diagram that illustrates features of the benefits of GPS data in precise paging in the operation of networks
  • Figure 2B is a block diagram that illustrates features of the benefits of GPS data for emergency responders
  • Figure 2C is a block diagram that illustrates features of the benefits of GPS data in computing a precise handset transmission signal strength in the operation of handsets of the networks;
  • FIGS. 3A and 3B are block diagrams that illustrate features of different embodiments of using GPS data in the Registration-Request Signal Transmission Management logic
  • Figure 4A and 4B are logic block diagrams that illustrate operation of the R-R Signal management function
  • Figure 4C is a block diagram that illustrates features of the logic operating in the mobile switching center for retrieving the device GPS location data from a received R-R signal and saving the same in the HLR database
  • Figure 5A and 5B are logic block diagrams for the mobile switching center (MSC) that illustrate operation of one the features of the embodiments herein that of accurate paging of cell phone
  • Figure 6A, 6B, 6C, and 6D are block diagrams for the mobile switching center (MSC) and the Emergency Response System that illustrate operation of one the features of the embodiments herein that of routing a 91 1 emergency call
  • Figure 7A and 7B are logic block diagrams for the mobile switching center (MSC) that illustrate operation of one the features of the embodiments herein that of computing device's signal transmission strength;
  • Figure 8 is method diagram for using GPS data of the cell phone device in the operation of the cellular communication networks.
  • a cellular communication network 14 has cell towers 1 6, a base station 18, and a mobile switching center (MSC) 19 working in conjunction with a HLR database 20.
  • the network 14 via the cell towers 16 communicates with handsets 12 that are part of the operation of the cellular communication network 14.
  • the handset 12 has GPS function 22, optionally a Gyro function 24 and an R-R Signal Transmission management function 10.
  • the registration request signal transmission management (RRSTM) function 10 embeds the handset location data from the GPS function 22 as part of the R-R signal 26 so that the record 27 that is transmitted over the control channel from the handset 12 has in addition to mobile identity number MIN 27A, electronic serial number ESN 27B, the global positioning system GPS location data 27C.
  • the MSC 19 receives R-R signals 26 from handsets 1 2 that contain in the record 27, in addition to MIN 27A and ESN 27B, the GPS location data 27C. The MSC 19 uses this data to maintain a HLR database 20.
  • the HLR database 20 maintains a GPS location data 27C of a mobile handset 12 referenced by a mobile identification number (MIN) 27A and a electronic serial number (ESN) 27B in addition to a geographic cell number 27D in an HLR database 20 for handsets 12 operating in the network 14.
  • MIN mobile identification number
  • ESN electronic serial number
  • the HLR database many also store other subscriber data including privileges and account standing.
  • the GPS location data 27C in the HLR database 20 may be used for more efficient paging to the handset 1 2 to route an incoming call 28 to the handset 12.
  • the GPS location data 27C in the HLR database 20 may also be used for more efficient response to the emergency responders 29 via a 91 1 logic 30 that may operate in the MSC 1 9 or preferably may operate in a separate server attached or interfaced to the MSC 19.
  • the GPS location data 27C in the HLR database 20 may also be used to program the handsets 1 2 with the handset transmission signal strength 31 based on the handset's relative location to the cell towers 1 6, in lieu of prior art triangulation algorithms.
  • FIGA and 3B illustrate the operation of the RRSTM and how the R- R signal transmission logic in the handset is used to embed GPS location data.
  • FIGs 4A and 4B illustrate how the R-R signal management function logic keeps track of handset movements and suppresses R-R transmissions when the handset 12 has not physically changed its position more than 100 feet.
  • the MSC 1 9 of the network 14 receives and processes an R-R record 27 from the handset 12 that contains GPS location data 27C and stores GPS location data 27C in the HLR database 20.
  • Figures 5A and 5B illustrate operation of the logic in the MSC 19 that makes use of the GPS location data in the HLR database 20 for accurate paging of the cell phones for routing incoming calls.
  • Figures 6A, 6B, 6C, and 6D illustrate operation of a 91 1 emergency call routing system for 91 1 calls originating in the wireless network.
  • FIGS 7A and 7B illustrate operation of the logic in the MSC 19 that makes use of the GPS location data in the HLR database 20 for accurate computing of the device's signal transmission strength to enhance device battery life in lieu of prior art triangulation approach.
  • the cellular network carrier which one of these features described herein to use and not use to enhance the operation of the network.
  • Figure 8 is a method diagram of the operation of the cellular
  • FIG. 3A illustrates the RRSTM function 1 0.
  • a timer function 30 that is driven by a clock signal 48.
  • Part of the phone logic keeps phone identification data called IMEI.
  • a function 32 gets the IMEI data.
  • a function 33 creates a transmission record using the IMEI data.
  • the function 34 also gets and embeds the GPS location data.
  • a function 35 then checks the timer to see if the time elapsed in equal five seconds. If the time elapsed in five seconds, the RRSTM logic 1 1 is activated. The details of the logic 1 1 are described with respect to Figure 3B.
  • the RRSTM logic 36 requires input of cell phone location 46. When the logic returns from the RRSTM logic 1 1 , the function 37 to send transmission command is executed.
  • the function 38 executes the transmission logic.
  • Figure 3B illustrates the functions of the RRSTM logic 1 1 . These functions are (i) set up and run an elapsed time timer, 50 (ii) Input/receive cell phone locations at every elapsed time interval 52, (iii) compute change in location (LChangeDelta) between current and immediate prior location 54, (iv) compare change in location (LChangeDelta) is less than a threshold 56, (v) if yes the Registration-Request message transmission is suppressed 58, If no, go to input cell phone location for the next loop 60.
  • the logic has the basic steps as illustrated.
  • the cell phone location as determined by GPS function may be sufficient for the operation of the RRSTM logic.
  • the steps are self explanatory as follows.
  • the logic starts 62.
  • the device location with the help of GPS function 66 is determined.
  • time elapsed counter is checked.
  • the new location of the device with the help of GPS function 66 is determined.
  • the RR signal is broadcast or its broadcast is not suppressed. If the change is less than 100 feet, then the broadcast of the RR signal is suppressed by looping back to step 64 to begin a new loop.
  • the global positioning satellite (GPS) system for commercial applications may not provide a location precision that is less than 100 feet change is location.
  • the figure of 100 feet in step 72 is used as an illustration to illustrate how the logic works.
  • the figure 100 feet may be any number that represents a threshold for the change in location for which the RR broadcast is either suppressed or not suppressed.
  • the figure of 100 feet may be chosen to represent a threshold that the device has not moved at all from its present location for the purposes of the RR logic. Further a GPS provided location resolution to 100 feet of the cell phone device may be considered adequate for emergency response system as well as other applications.
  • the logic has the steps as illustrated. In
  • FIG. 4B a rate of location change logic steps 71 and 73 have been added that determine if the cell phone is in a vehicle in motion. Further many phones now come equipped with a gyro function 67 that can more precisely determine change is location and that may work in conjunction with the GPS function 66. In that case the logic to suppress Registration-Request Signal transmissions is bypassed and the logic continuously loops to detect a change in the movement of the cell phone.
  • the system may have a function that computes a rate of change of location and if the rate is above a threshold, indicative of a rapidly moving physical location, the function does not suppress the prior art Registration- Request Signal transmissions to the network.
  • the system may have a function to detect a previous and a current location of the cell phone device, receives location inputs from a combination of a GPS function and a gyro function in the device to have a more precise cell phone location to compute the change is location and the rate of change in location of the cell phone device.
  • a system that works in conjunction with a cellular telephone network has a Registration-Request Signal transmission management function that operates in the device and periodically detects change in physical location of the device from an immediate prior location, called an LchangeDelta. The function, if the LchangeDelta keeps the device in a cell space boundary, suppresses a prior art Registration-Request Signal transmission from the device to the cellular network.
  • the function if the LchangeDelta moves a device out of the cell boundary, does not suppress the prior art Registration-Request Signal transmission from the device to the cellular network.
  • the handset 12 operating as part of the network 14 is programmed to include GPS location data as part of an R-R transmission record 27.
  • the handset 12 operating as part of the network 14 is also programmed to update its GPS location data when the handset 12 detects a physical movement in the handset location that exceeds 100 feet from a prior location.
  • a cellular communication network 14 has a HLR database 20 of a mobile switching center (MSC) 1 9 of a cellular communication network that maintains a GPS location data 27C of a mobile handset 1 2.
  • the GPS location data 27C is maintained in the HLR database 20 with reference to a mobile identification number (MIN) 27A and an electronic serial number (ESN) 27B.
  • MIN mobile identification number
  • ESN electronic serial number
  • the HLR database 20 may be part of the MSC 19. Alternatively, the
  • HLR database 20 may operate independently of the MSC 1 9 and serve the MSC 19 as well as other applications. On request, the HLR database 20 sends the GPS location data of the handsets to an application. These applications may include an application that is resident and operating in the MSC 1 9 itself or the application may be resident and operating in an entity outside of the MSC 19. These applications may include commercial applications that have been contracted for between the commercial and government entities and the cellular network carrier companies.
  • the MSC 1 9 of the network As illustrated with reference to Figure 4C, the MSC 1 9 of the network
  • Logic 14 has MSC logic 80.
  • Logic 80 receives and processes an R-R record 27 from the handset 12 that contains GPS location data 27C and stores GPS location data 27C in the HLR database 20.
  • Logic 80 has the following functions. Function 81 receives R-R signal record 27 from handsets 12 operating in the wireless network. Function 82 processes the R-R signal record from the handset. Function 83 extracts ESN & MIN data from the R-R record and saves in the HLR database. Function 84 extracts handset GPS location data from the R-R record and save the handset GPS location data in lat/long in the HLR database. Function 85 saves the identification of the cells which picked up the R-R signal transmission.
  • Logic 80 functions as described above may be performed in any order and not necessarily the order they are shown in Figure 4C.
  • the end result of the logic 80 is that the HLR database has the GPS location data of the handset 12, in addition to the data already present in the HLR database as in prior art.
  • the routing logic 90 operates in the MSC 1 9 in conjunction with the HLR database 20 for routing a received incoming call to a called device 1 2.
  • the logic 90 first pages by sending a page command in the specific cell where the device 12 is located.
  • the specific cell identification has been determined from the device 12 GPS location data in the HLR database 20.
  • the device 12 responds to the page and the call is routed to the device 12 in that specific cell.
  • Function 91 processes the incoming call for routing.
  • Function 92 parse the destination number of the called device and Check its presence in the HLR database 20.
  • Function 93 from the HLR database 20, finds the last known cell identifications of the device 12.
  • Function 94 retrieves the GPS Location data of the device 12 from HLR database 20. Function 95 using these data of the last known cell identifications and the current GPS location data in latitude longitude of the device 12 determines the specific cell identification of the device 12. Knowing the device 12's lat/long from the HLR database helps determine the exact and specific cell identification, the device is at the time of the incoming call.
  • Function 96 send a page command to the specific cell Id.
  • Function 97 waits for page response from the device 1 2.
  • Function 98 sets up call data.
  • Function 99 routes the incoming call to the identified cell towers in the specific cell.
  • the wireless network has emergency-responder logic 100 in the MSC
  • the logic 100 As illustrated with the help of Figure 6A, the logic 100, as shown by the dotted box has different parts that operate and execute in three different places.
  • the logic 100 operates in (i) as part of the call routing logic 1 00A, (ii) as part of the 91 1 logic 1 00B, (iii) and as logic 100C as part of the emergency responder database 200.
  • the call routing logic 100A for a received
  • 91 1 emergency call from the cell phone device 12, parses the caller id and checks for that caller id in the HLR database 20.
  • the logic 100A finds the last known cell area id and retrieves the handset GPS location data from the HLR database 20.
  • the logic 100A then sends the call control to a 91 1 logic 100B.
  • the 91 1 logic 100B may be part of the MSC system by being co-located or may be operative in another location that is accessible by any MSC 1 9 over the Internet.
  • the 91 1 logic 100B works in conjunction with logic 100C that is interfaced with an Emergency Responder Data and Physical Address database 200.
  • the 91 1 logic 100B receives the latitude longitude data of the calling device 12 and with the help of database 200 maps that location to the nearest ER region.
  • the 91 1 logic 100B also maps the latitude longitude data to the nearest physical address of the device, again using the database 200.
  • the logic 100C provides for the search logic and may operate as part of the database servers and provides an interface to the data in the database 200 to search and fetch the ER region data and the physical address data of the device corresponding to a latitude longitude value.
  • search logic is considered prior art is used in many prior art applications to search a database.
  • the database 200 may be managed by a different business entity then the wireless carrier.
  • the database 200 may maintain data related to the entire United States and serve a multiple wireless carriers as well as other businesses.
  • the logic 100C serves as an interface between the logic 1 00B and the database 200.
  • Logic 1 00B based on the latitude longitude data of the handset 12 receives via logic 100C two different data sets identified as data set A and data set B.
  • the data set A provides the ER region that would be responsible for handling this emergency response and its landline contact number for routing the 91 1 call to that landline number.
  • the dataset B provides the actual physical address where the handset 12 is currently located.
  • Logic 100B having received these two data sets A and B format a record and sends the record to the logic 100A. Then the 91 1 logic 100B sends both of these data to the logic 100A.
  • the logic 100A then embeds physical address data in the call and routes the 91 1 call to the Emergency Responder 29 for the ER region and sets up a live call connection between the device and the ER 29.
  • the database 200 has two different databases 200A and 200B.
  • the database 200A stores the data relate to different ER regions. For each ER region, the database stores regions id, address, telephone, contact, region boundary, map and latitude longitude boundaries.
  • the database 200 is used to map the latitude longitude data of a received 91 1 call to a specific ER region that would respond to the call.
  • the database 200A sends the landline telephone number of the ER region to the logic 90 for it to route the 91 1 call to that landline number.
  • the database 200B identifies the cities of each ER region of database 200A and the physical addresses present in each of these cities and the latitude longitude of each such address.
  • the database 200B also identifies the other parts of the city such as various landmarks, parks, streets, and Freeways.
  • the database 200B maps a latitude longitude data of a received 91 1 call to one of these physical addresses.
  • the database 200 maps the GPS location data to a physical address and, sends a text message with the physical address to the emergency system.
  • the mapping to a physical address from a GPS location data in latitude and longitude dimensions is prior art.
  • the mapping may be done by a tabular look up of the physical addresses that map to the GPS location data.
  • the Emergency Responder System 29 is illustrated with reference to Figure 6C. What is illustrated is that a incoming 91 1 call is received by a call handling logic and this logic based on the availability of the Stations routes the call to a particular station manned by an agent.
  • Each station has a display screen and an audio head phone being used by the agent to receive and respond to the 91 1 call.
  • the station displays meta data such as sequence time date and also displays city, telephone and the physical address of the calling device for the 91 1 call.
  • the 91 1 logic may also support display of if the cell phone is in a vehicle that is in motion.
  • the other parts of the display provide for operator notes and dialogue and dispatch notes if any.
  • the 91 1 meta and dialogue and dispatch/resolution data is appropriately formatted and simultaneously being sent and being recorded on a tape storage.
  • the audio feed as heard on the headphone also overlays the physical address in addition to displaying on the display screen.
  • FIG. 6D provided a simplified illustration of the different functions of logic 100.
  • Function 1 01 processes the incoming call for routing.
  • Function 1 02 retrieves location data from the HLR database.
  • Function 1 03 converts the latitude longitude data to a physical address.
  • Function 104 creates a text message and sends to the emergency system.
  • Function 1 05 performs a text to speech conversion of the physical address and function 106 embeds the physical address in the voice call as overlaid audio.
  • Function 107 routes the call the emergency system 29.
  • the emergency responder logic 1 00A in the MSC for a received 91 1 emergency call from the handset 12 retrieves the handset GPS location data 27C from the HLR database 20.
  • the logic 1 00B maps the GPS location data 27C to a physical address.
  • Logic 1 00A then performs a text to speech conversion of the physical address.
  • the technologies that support text to speech conversion are prior art.
  • the logic 1 00A also may have a function that overlays the speech version of the physical address in a routed 91 1 call to the emergency system 29.
  • the logic 1 10 operates in the MSC 19 for computing the device's 12 optimum signal transmission strength based on the location of the device in a given cell area respective to the distance to the nearest cell telephone towers.
  • Logic 1 10 working in conjunction with the HLR database 1 0 computes the device 12 optimum signal transmission strength for optimizing battery usage of device 12.
  • Logic 1 10 receives R-R signal record 27 from the device 12 and sends the precise signal strength 31 to the device 12 via the wireless network 14.
  • the logic 1 10 receives an R-R signal transmission from the device, and updates the HLR database with the cell id and the device's GPS location data as had been described earlier with reference to logic 90.
  • the logic 1 10 reads the current GPS location data of the device and computes the device's transmission signal strength for transmission to the nearest cell tower in the cell area and sends that signal strength to the wireless device over the control channel for the device to store in the device.
  • This approach it is believed is preferable to computing the device signal transmission strength via prior art triangulation techniques that depends upon the MSC 19 receiving signal from the device at least three cell towers at full power and then based on the relative received signal strength at each cell tower and knowing the geographical placement of each cell tower, to compute the device's location in that cell as well as its distance to the nearest cell tower.
  • logic 1 10 The functions of logic 1 10 are illustrated with reference to Figure 7B.
  • function 1 1 1 1 receives R-R signal and verifies Id in HLR database 20.
  • Function 1 1 2 saves GPS Location data of the device 12 in the HLR database 20.
  • Function 1 13 reads Cell Identifications of the handset 12 in the database 20.
  • Function 1 14 reads current GPS lat/long of the device 12.
  • Function 1 15 computes exact cell id from the GPS location data.
  • Function 1 16 computes distance of the device 12 to closest cell tower in the specific cell space.
  • Function 1 1 7 sends/transmits a signal strength management command to the handset.
  • the function 1 18 repeats the process if GPS location data of the device 12, in the database has changed signifying movement of the handset 12 relative to the cell towers.
  • the network 14 sends to the handset 1 2 a handset transmission signal strength 31 , based on the distance of the GPS location of the handset 12 from the cell towers in the cell area in lieu of performing a triangulation logic.
  • a mobile wireless cell phone device operating as apart of a wireless communication network has a GPS function.
  • a registration request signal transmission management (RRSTM) logic operating in the cell phone device creates a registration-request (R-R) record and embeds a GPS location data of the device in the record in addition to the international mobility equipment identifier (IMEI) data of the device in the record.
  • the logic sends the R-R record with the GPS location data to the wireless network.
  • the device receives from the network a device transmission signal strength, as computed by the network based on a distance of the GPS location of the device to the cell towers in the cell area, in lieu of the network performing a triangulation logic to compute the location of the device in the cell area.
  • the device stores the received transmission signal strength and uses that data to calibrate the transmission signal strength of an outgoing voice and data transmission to the network to economize on the battery of the device.
  • the device operating as part of the wireless network, is programmed to include GPS location data of the device as part of a R-R transmission record to the network.
  • the device operating as part of the wireless network is programmed to update its GPS location data for inclusion in the R-R record and transmit the R-R record when the device detects a physical movement in the device location that exceeds a threshold equal to 1 00 feet from a prior location.
  • a wireless network operating in conjunction with wireless mobile devices has a mobile switching center (MSC) with a home location record (HLR) database that stores subscriber Id data of cell phone devices that are subscribed to and are operating in the network.
  • the network receives and processes a R-R record from the cell phone devices, the records contains a GPS location data of the devices and the network stores the GPS location data of the devices in the HLR database.
  • the network sends to the device, a handset transmission signal strength, as computed by the network based on the distance of the GPS location of the handset from the cell towers in the cell area, in lieu of performing a triangulation logic.
  • the MSC for routing a received call into the network from a calling telephone device to a called cell phone device pages the called device only in the specific cell location that is mapped from the GPS location data of the device in the HLR database, in lieu of paging all the surrounding cells from a last known cell location of the cell phone device.
  • a cellular communication network has a HLR database of a mobile switching center (MSC) of a cellular communication network that maintains a GPS location data of a mobile cell phone device.
  • the GPS location data is maintained in the HLR database with reference to a mobile identification number (MIN) and a electronic serial number (ESN).
  • MIN mobile identification number
  • ESN electronic serial number
  • the HLR database on request received by the network, sends the GPS location data of the device with the device identifier to a system hosting an application.
  • the application may include an application that is resident and operating in the MSC itself or the application may be resident and operating in a system by an entity outside of the MSC.
  • a cellular communication network based emergency response system has a mobile switching center (MSC) of a cellular communication network that maintains, in an home location record (HLR) database, a GPS location data of a mobile cell phone device, for devices that are operating in the network.
  • the MSC has an interface to an emergency response (ER) system.
  • the MSC for a received 91 1 emergency call from a wireless device retrieves the device's GPS location data from the HLR database and sends to the ER system over the interface.
  • An emergency response logic in the ER system maps the received
  • GPS location data to (i) an ER region contact data from a pre-stored ER region contact database and (ii) maps the GPS location data to a physical address of the device.
  • the logic creates and sends a record with the ER region contact data and the device's physical address data to the MSC over the interface.
  • the MSC receives the record and routs the 91 1 call to the ER region contact landline.
  • the logic embeds a text/voice message with the physical address of the device or sends a separate text message record.
  • the MSC for a received 91 1 emergency call from a device retrieves the device's GPS location data from the HLR database and routs the call with the location data to an ER system.
  • An emergency responder logic in the ER system maps the received GPS location data to (i) an ER region contact data and (ii) to a physical address of the device.
  • the logic routs the call to a landline number of the ER region and embeds a text message with the physical address of the handset to the ER region.
  • An emergency responder logic in the MSC for a received 91 1 emergency call from the device retrieves the device's GPS location data, maps to a physical address and performs a text to speech conversion of the physical address and embeds the physical address in a routed 91 1 call to the emergency system.
  • An emergency response system for a wireless network has a logic that is operable in a server of the emergency response system that receives a lat/long data of a received 91 1 call, of a cell phone device operating in the wireless network, from a mobile switching center of the wireless network. The logic interfaces with an ER database system, the ER database system maps the lat/long data to a physical address and the logic retrieves the device's physical address from the database.
  • the logic sends the physical address data to the mobile switching center.
  • the ER database system also sends to the logic the ER region where the device is located and the landline number of the ER region.
  • the logic sends both the device's physical address and the ER region landline number to the mobile switching center for the mobile switching center, thereby the mobile switching center is able to route the 91 1 emergency call to the specific ER region where the device is located as well as the physical address of the device.
  • the ER database system stores the cities in each of the ER regions and the physical addresses in each city along with their lat/long data.
  • the ER database system stores ER region details including address and landline contact numbers.
  • the ER database system stores for each of the cities in each of the ER regions, the landmarks including parks, highways, libraries, points of interest and their physical addresses along with their lat/long data.
  • a method for enhancing the efficiency of a cellular communication network has the following steps where all the steps may not be used or used in the order specified.
  • step 1 maintaining in a mobile switching center (MSC) of a cellular communication network, a GPS location data of a mobile handset, referenced by a mobile identification number (MIN) and an electronic serial number (ESN), in addition to a geographic cell number, in an HLR database for the handsets, operating in the network.
  • MSC mobile switching center
  • ESN electronic serial number
  • step 1 22 retrieving by emergency responder logic in the MSC, for a received 91 1 emergency call, the GPS location data of the handset, from the HLR database, and converting the GPS physical data to a physical address, and sending a text message with the physical address to an emergency response system.
  • step 1 24 retrieving by the emergency responder logic in the MSC, for a received 91 1 emergency call, the GPS location data of the handset from the HLR database, and converting the GPS location data to a physical address, performing a text to speech conversion of the physical address and embedding in the voice call before routing the call to the emergency response system.
  • step 128 sending by the network to the handset, a handset transmission signal strength, based on the distance of the GPS location of the handset from the cell towers in the cell area in lieu of performing a
  • step 1 receiving and processing by the network an R-R record that contains GPS location data and stores GPS location data in the HLR database.
  • step 1 32 programming the handset operating as part of the network to include GPS location data as part of an R-R transmission record.
  • step 1 34 programming the handset, operating as part of the network, to update its GPS location data when the handset has moved more than 100 feet.
  • a method for a mobile wireless cell phone device, operating as apart of a wireless communication network has the following steps, where all the steps may not be used or used in the order specified:
  • RTSTM Radio Resource Management
  • R-R registration-request
  • IMEI international mobility equipment identifier
  • d. receiving by the device from the network a device transmission signal strength, as computed by the network based on a distance of the GPS location of the device to the cell towers in the cell area, in lieu of the network performing a triangulation logic to compute the location of the device.
  • the device operating as part of the wireless network, to include GPS location data as part of a R-R transmission record.
  • programming the device operating as part of the wireless network to update its GPS location data for inclusion in the R-R record and send the R-R record when the device detects a physical movement in the device's location that exceeds 100 feet from a prior location.
  • a method for a wireless network operating in conjunction with mobile wireless devices has the following steps where all the steps may not be used or used in the order specified:
  • a. having by the wireless network a mobile switching center (MSC) with a home location record (HLR) database that stores subscriber Id data of cell phone devices that are subscribed to and are operating in the network; b. receiving and processing by the network a R-R record from the cell phone devices, the records containing a GPS location data of the devices and the network storing the GPS location data of the devices in the HLR database.
  • MSC mobile switching center
  • HLR home location record
  • c. sending by the network to the device, a device transmission signal strength, as computed by the network based on the distance of the GPS location of the device from the cell towers in the cell area, in lieu of performing a triangulation logic.
  • paging by the MSC for routing a received call into the network from a calling telephone device to a called cell phone device, only the called device in the specific cell location that is mapped from the GPS location data of the device in the HLR database, in lieu of paging all the surrounding cells from a last known cell location of the cell phone device.
  • a method for cellular communication network based emergency response system has the following steps where all the steps may not be used or used in the order specified:
  • a mobile switching center MSC
  • HLR home location record
  • ER emergency response
  • mapping by an emergency responder logic in the ER system mapping the received GPS location data to (i) an ER region contact data and (ii) to a physical address of the handset; i. routing by the logic the call to a landline number of the ER region and embeds a text message with the physical address of the device to the ER region.
  • a method of a cellular communication network operation has the following steps where all the steps may not be used or used in the order specified:
  • a maintaining in a mobile switching center (MSC) of a cellular communication network, a GPS location data of a mobile handset, referenced by a mobile identification number (MIN) and an electronic serial number (ESN), in addition to a geographic cell number, in an HLR database for the cell phone devices, operating in the network.
  • MSC mobile switching center
  • MIN mobile identification number
  • ESN electronic serial number
  • a cellular communication network with a mobile switching center (MSC) of a cellular communication network maintains a GPS location data of a mobile handset referenced by a mobile identification number (MIN) and an electronic serial number (ESN) in addition to a geographic cell number in an HLR database for handsets operating in the network.
  • MSC mobile switching center
  • the network uses the GPS location data of the handsets in its network for different purposes, these may include, (i) efficient paging for routing incoming calls, (ii) efficient location data response to emergency responders, and (iii) more efficient management of battery in the handsets.

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Abstract

A cellular communication network has a mobile switching center (MSC) that maintains a GPS location data of a mobile handset referenced by a mobile identification number (MIN) and an electronic serial number (ESN) in addition to a geographic cell number in an HLR database for handsets operating in the network. The GPS location data of the handset may be used for efficient paging to a specific cell to route incoming calls to the handset, route emergency responder calls with the physical location of the handset and to program the handset with the handset transmission strength to the nearest cell tower In lieu of using triangulation algorithm.

Description

SYSTEM AND METHOD FOR EFFICIENT OPERATION OF CELLULAR COMMUNICATION NETWORKS CROSS REFERENCE
This application claims priority from U.S. Application No. 61 /61 2,889, filed March 19, 2012 titled, "System and Method for Efficient Operation of Cellular Communication Networks" and U.S. Application No. 13/473,493 filed May 16, 202 titled, "System and Method for Efficient Operation of Cellular Communication Networks". This application is related to Provisional
Application Serial Number 61 /631 ,527, filed January 5, 2012 titled, "A System Using GPS to Enhance Battery Life in Handheld Wireless Mobile Devices", all of which are incorporated herein in entirety as far as permitted.
FIELD OF THE INVENTION
A system using GPS location of cell phone devices to improve the operation of cellular communication networks is described. The system uses cell phone devices that use Registration-Request Signal transmission from the cell phone device to convey GPS location of the device to the wireless network.
BACKGROUND
Cellular communication networks operate with and have cell phone devices, sometimes called handsets, cell towers, base stations, mobile switching center (MSC), with access to home location record (HLR) database that maintain subscriber data including their present location by a geographic cell number. The handsets communicate to the network via the cell towers on control and data channels. Networks detect registration-request (R-R) signals on the control channel from the handset and record in the HLR database the presence of the handset in the cell the handset sent the R-R signal from.
The operation of cellular network depends on knowing the general location of the handset in a group of cells to page the handset in those contiguous cell areas and route a call to the given cell area from which the handset responds to the page. That general location of the handset in the HLR database requires the MSC to page a handset in multiple cells based on last known area.
Cellular networks rely on a technique known as triangulation based on signal strength received from the handset at a minimum of three different cell towers. The measured received signal strength is used for computing a location of the handset in the cell space using a triangulation algorithm. This approach of triangulation to determine the physical location of the handset within a cell space is used for both battery management in the handset and also used for 91 1 emergency calls to provide a location of the handset to the emergency responders as required by a 91 1 federal mandate.
Almost all handsets now come equipped with and have GPS functionality. Many commercial enterprises have figured out ways to use the GPS functionality in the handsets for marketing purposes. It is believed that the same GPS functionality in handsets may be used in a number of different ways to improve the operation of the cellular communication networks.
Hence, it is an objective of the embodiments herein to provide for systems and methods to improve operation of cellular networks using GPS functionality that is already embedded in the handsets/cell phone devices.
SUMMARY
In the prior art landline based telephone system, the telephone company always knew of the physical location of a call originated on a landline telephone device. With the advent of the cellular wireless network and the cell phone devices that operate with such a wireless network that is not possible as the cell phone device is mobile and may be in any location in a geographic area.
The embodiments described herein enable the wireless networks to maintain a precise location of the cell phone devices at all the times. Such embodiments are useful for many purposes, not the least of which is to route 91 1 emergency calls originating via the mobile cell phone device. The other purpose is to provide an efficient operation of the wireless cellular network then that has been possible in the prior art cellular telephone networks.
Before providing a summary of the embodiments herein, the operation of a cellular telephone network is described in a tutorial manner, which it is believed, would help a reader better understand the embodiments described herein. In the content that follows, the terms handset, cell phone, cell phone device, and device have been used interchangeably.
In a cellular telephone network, geographic space over which cellular service is provided is partitioned in to a large number of geographic cells. Each geographic cell is about a few square miles and is covered by multiple cellular tower antennas. Coverage of a cell area by three towers is preferred, as the three cell towers by measuring the relative strength of the cell phone transmission and by using triangulation can determine the location of the cell phone within the cell space.
This location of the cell phone within the cell itself is not required for the cellular telephone network operation itself. However, the cellular network may use this location information of the cell phone within the geographic cell for purposes other than cellular network operation. One such purpose is to support a federal 91 1 mandate. Other such purpose is to reduce the transmission power of the cell phone based on distance to the nearest tower to minimize battery usage and thus enhance battery life. The cell phones are mobile and based on the cell phone owner's life style and vocation a cell phone may move within a cell space, not move at all, or move rapidly across many cells such as when the cell phone owner is in a vehicle in motion or is in a flight. Thus the cell phones may therefore either not change their cell location or change their cell location slowly, or change rapidly and unpredictably. Therefore, as part of the cellular telephone network operation, it is necessary for the cellular network to know in which specific geographic cell the cell phone is physically located at any given time. To provide that specific geographic cell location information to the cellular network, cell phones have been designed to periodically broadcast an identity signal, called Registration-Request Signal (RRS) that is used by the cellular network to determine and then save the geographic cell location of a wireless mobile cell phone in a network database. The network database is maintained by the cellular carrier and is referenced to and used for routing incoming calls to the specific cell where the cell phone is located.
Based on the speed and unpredictable nature with which a cell phone may move and thus potentially cross geographic boundary of a cell space, the Registration-Request Signal (RRS) is broadcast by the cell phone every few seconds. The RRS should not be confused with the roaming and roaming signal which uses the same Registration-Request Signal in a cell phone to operate in a cellular carrier area that is not covered by the home carrier with which the cell phone owner has contracted for the cell telephone service.
The location of the cell phone in a specific cell that is maintained in the network database is used to route incoming calls to the geographic cell where the cell phone is located. These incoming calls may originate in any part of the landline and cellular network nationally or globally.
The cellular network uses these Registration-Request Signals from the devices to record and maintain in a database the current cell location of the device. The database is used to determine the current cell location of the device so that the incoming calls are routed to the specific cell where the device is located based on the Registration-Request Signals being transmitted from the device to the network.
Two different aspects of the efficient cellular network operation technology are described herein. The first of these aspects minimizes or suppresses the transmission of the R-R Signal from the cell phone device when the cell phone has not moved more than 100 feet from an immediate prior location. The second aspect is that the R-R Signal transmission embeds the GPS location data of the cell phone device.
Both of these aspects are capable of independent operation of each other. First of these aspects has been described earlier in another pending application of the applicant as a means to economize on the battery life of the cell phone device. Both of these aspects of technology working together provide for a more efficient cellular network operation as described in the embodiments herein. The first as well as the second of these aspects and their benefits are described in detail in this application.
It is not easy to predict when the cell phone of an individual user would move and if it does move how much does it move relative to a cell space, as that would be a function of the life style and cell phone use characteristics of an individual. Further, it is not easy to predict when the cell phone would move in a vehicle requiring constant transmissions of the Registration- Request Signal, as currently provided in the prior art technology. The location of the cell phone would change rapidly based on the speed of the vehicle.
The embodiments described herein provide a Registration-Request Signal Transmission Management (RRSTM) logic that would manage and optimize the Registration-Request Signal transmissions from the cell phone device based on the individual user behavior of using a cell phone. That is, determine when the cell phone has moved and how much it has moved relative to a geographic cell and use that information to either not suppress prior art Registration-Request Signal transmissions or suppress such prior art Registration-Request Signal transmissions. Dynamically adjusting the rate of Registration-Request Signal transmission that is made possible by the RRSTM logic does not affect the cellular operation of the cell phone as any use of the cell phone is not affected by dynamically adjusting the Registration-Request Signal transmission as had been described above. The prior art Registration-Request Signal
transmissions work independently of the actual use of a cell phone for receiving and initiating calls to other phones. A cell phone working in conjunction with a cellular network uses control channels and data channels. The control channel is used for communicating and exchanging control data such as RR signal and to communicate voice/data channels to be used for a given voice/data connection. Hence the use of the control channel for RR signal does not affect the operation of the cell phone in sending and receiving voice and data transmissions.
As described in the embodiments herein, the R-R logic in handsets is modified to include a current GPS location data of the cell phone device in the R-R record. The wireless network from the received R-R record retrieves the GPS location data of the cell phone devices and saves in the HLR database. By modifying the R-R logic to embed GPS location data, the HLR database is able to maintain such location data in the HLR database.
Maintaining such GPS location data in the HLR database provides multiple benefits for improving the operation of the wireless networks. One of these benefits is that of accurate paging of the cell phones for routing incoming calls. Another of these benefits is to be able to provide for wireless network originated 91 1 calls, the seamless location of the cell phone device to emergency responders. Yet another benefit may also be to calibrate the device's signal transmission strength in lieu of using triangulation algorithms that are used in prior art.
These and other aspects of the embodiments herein are further described in detail with the help of the accompanying drawings and the description, where similar number are used to identify the features of the embodiments.
BRIEF DESCRIPTION OF THE DRAWINGS Some of the novel features of the embodiments will be best understood from the accompanying drawings, taken in conjunction with the accompanying description, in which similar reference characters refer to similar parts, and in which: Figures 1 is a block diagram that illustrates the features of GPS location data in the operation of the cellular communication network;
Figure 2A is a block diagram that illustrates features of the benefits of GPS data in precise paging in the operation of networks;
Figure 2B is a block diagram that illustrates features of the benefits of GPS data for emergency responders;
Figure 2C is a block diagram that illustrates features of the benefits of GPS data in computing a precise handset transmission signal strength in the operation of handsets of the networks;
Figure 3A and 3B, are block diagrams that illustrate features of different embodiments of using GPS data in the Registration-Request Signal Transmission Management logic;
Figure 4A and 4B are logic block diagrams that illustrate operation of the R-R Signal management function; Figure 4C is a block diagram that illustrates features of the logic operating in the mobile switching center for retrieving the device GPS location data from a received R-R signal and saving the same in the HLR database; Figure 5A and 5B are logic block diagrams for the mobile switching center (MSC) that illustrate operation of one the features of the embodiments herein that of accurate paging of cell phone; Figure 6A, 6B, 6C, and 6D are block diagrams for the mobile switching center (MSC) and the Emergency Response System that illustrate operation of one the features of the embodiments herein that of routing a 91 1 emergency call; Figure 7A and 7B are logic block diagrams for the mobile switching center (MSC) that illustrate operation of one the features of the embodiments herein that of computing device's signal transmission strength;
Figure 8 is method diagram for using GPS data of the cell phone device in the operation of the cellular communication networks.
DESCRIPTION
Introduction
As illustrated with reference to Figure 1 , a cellular communication network 14 has cell towers 1 6, a base station 18, and a mobile switching center (MSC) 19 working in conjunction with a HLR database 20. The network 14 via the cell towers 16 communicates with handsets 12 that are part of the operation of the cellular communication network 14.
The handset 12 has GPS function 22, optionally a Gyro function 24 and an R-R Signal Transmission management function 10.
The registration request signal transmission management (RRSTM) function 10 embeds the handset location data from the GPS function 22 as part of the R-R signal 26 so that the record 27 that is transmitted over the control channel from the handset 12 has in addition to mobile identity number MIN 27A, electronic serial number ESN 27B, the global positioning system GPS location data 27C. The MSC 19 receives R-R signals 26 from handsets 1 2 that contain in the record 27, in addition to MIN 27A and ESN 27B, the GPS location data 27C. The MSC 19 uses this data to maintain a HLR database 20. The HLR database 20 maintains a GPS location data 27C of a mobile handset 12 referenced by a mobile identification number (MIN) 27A and a electronic serial number (ESN) 27B in addition to a geographic cell number 27D in an HLR database 20 for handsets 12 operating in the network 14. The HLR database many also store other subscriber data including privileges and account standing.
As illustrated with reference to Figure 2A, the GPS location data 27C in the HLR database 20 may be used for more efficient paging to the handset 1 2 to route an incoming call 28 to the handset 12.
As illustrated in Figure 2B, the GPS location data 27C in the HLR database 20 may also be used for more efficient response to the emergency responders 29 via a 91 1 logic 30 that may operate in the MSC 1 9 or preferably may operate in a separate server attached or interfaced to the MSC 19.
As illustrated in Figure 2C, the GPS location data 27C in the HLR database 20 may also be used to program the handsets 1 2 with the handset transmission signal strength 31 based on the handset's relative location to the cell towers 1 6, in lieu of prior art triangulation algorithms.
Figure 3A and 3B illustrate the operation of the RRSTM and how the R- R signal transmission logic in the handset is used to embed GPS location data.
Figures 4A and 4B illustrate how the R-R signal management function logic keeps track of handset movements and suppresses R-R transmissions when the handset 12 has not physically changed its position more than 100 feet. As illustrated with reference to Figure 4C, the MSC 1 9 of the network 14 receives and processes an R-R record 27 from the handset 12 that contains GPS location data 27C and stores GPS location data 27C in the HLR database 20.
Figures 5A and 5B illustrate operation of the logic in the MSC 19 that makes use of the GPS location data in the HLR database 20 for accurate paging of the cell phones for routing incoming calls.
Figures 6A, 6B, 6C, and 6D illustrate operation of a 91 1 emergency call routing system for 91 1 calls originating in the wireless network.
Figures 7A and 7B illustrate operation of the logic in the MSC 19 that makes use of the GPS location data in the HLR database 20 for accurate computing of the device's signal transmission strength to enhance device battery life in lieu of prior art triangulation approach.
It is up to the cellular network carrier which one of these features described herein to use and not use to enhance the operation of the network. There may be more or different features and applications that may be supported by the HLR database and these are not ruled out. While some of these functions may be used to improve the operational efficiency of the cellular communication networks others may be used to possibly generate additional revenues by providing enhanced services to a number of businesses who may benefit from knowing the location of the network subscribers.
Figure 8 is a method diagram of the operation of the cellular
communication network with the features of the embodiments herein. These and other aspects of the embodiments herein are described in detail, where the headings are provided for reader convenience.
Registration-Request Signal Transmission Management Function 10 Figure 3A illustrates the RRSTM function 1 0. There is a timer function 30 that is driven by a clock signal 48. Part of the phone logic keeps phone identification data called IMEI. A function 32 gets the IMEI data. A function 33 creates a transmission record using the IMEI data. The function 34 also gets and embeds the GPS location data. A function 35 then checks the timer to see if the time elapsed in equal five seconds. If the time elapsed in five seconds, the RRSTM logic 1 1 is activated. The details of the logic 1 1 are described with respect to Figure 3B. The RRSTM logic 36 requires input of cell phone location 46. When the logic returns from the RRSTM logic 1 1 , the function 37 to send transmission command is executed. The function 38 executes the transmission logic.
Figure 3B illustrates the functions of the RRSTM logic 1 1 . These functions are (i) set up and run an elapsed time timer, 50 (ii) Input/receive cell phone locations at every elapsed time interval 52, (iii) compute change in location (LChangeDelta) between current and immediate prior location 54, (iv) compare change in location (LChangeDelta) is less than a threshold 56, (v) if yes the Registration-Request message transmission is suppressed 58, If no, go to input cell phone location for the next loop 60.
As illustrated in Figure 4A, the logic has the basic steps as illustrated. In this basic logic, the cell phone location as determined by GPS function may be sufficient for the operation of the RRSTM logic. The steps are self explanatory as follows. The logic starts 62. At step 64, the device location with the help of GPS function 66 is determined. At step 68, time elapsed counter is checked. At step 70 the new location of the device with the help of GPS function 66 is determined. At step 72, if the change in two locations is determined and if the change is greater than 100 feet, then at step 74, the RR signal is broadcast or its broadcast is not suppressed. If the change is less than 100 feet, then the broadcast of the RR signal is suppressed by looping back to step 64 to begin a new loop.
The global positioning satellite (GPS) system for commercial applications may not provide a location precision that is less than 100 feet change is location. The figure of 100 feet in step 72 is used as an illustration to illustrate how the logic works. The figure 100 feet may be any number that represents a threshold for the change in location for which the RR broadcast is either suppressed or not suppressed. The figure of 100 feet may be chosen to represent a threshold that the device has not moved at all from its present location for the purposes of the RR logic. Further a GPS provided location resolution to 100 feet of the cell phone device may be considered adequate for emergency response system as well as other applications. As illustrated in Figure 4B, the logic has the steps as illustrated. In
Figure 4B, a rate of location change logic steps 71 and 73 have been added that determine if the cell phone is in a vehicle in motion. Further many phones now come equipped with a gyro function 67 that can more precisely determine change is location and that may work in conjunction with the GPS function 66. In that case the logic to suppress Registration-Request Signal transmissions is bypassed and the logic continuously loops to detect a change in the movement of the cell phone.
The system may have a function that computes a rate of change of location and if the rate is above a threshold, indicative of a rapidly moving physical location, the function does not suppress the prior art Registration- Request Signal transmissions to the network.
The system may have a function to detect a previous and a current location of the cell phone device, receives location inputs from a combination of a GPS function and a gyro function in the device to have a more precise cell phone location to compute the change is location and the rate of change in location of the cell phone device. A system that works in conjunction with a cellular telephone network has a Registration-Request Signal transmission management function that operates in the device and periodically detects change in physical location of the device from an immediate prior location, called an LchangeDelta. The function, if the LchangeDelta keeps the device in a cell space boundary, suppresses a prior art Registration-Request Signal transmission from the device to the cellular network.
The function, if the LchangeDelta moves a device out of the cell boundary, does not suppress the prior art Registration-Request Signal transmission from the device to the cellular network.
Handset 12
The handset 12 operating as part of the network 14 is programmed to include GPS location data as part of an R-R transmission record 27. The handset 12 operating as part of the network 14 is also programmed to update its GPS location data when the handset 12 detects a physical movement in the handset location that exceeds 100 feet from a prior location. These functions of the handset have been described earlier with reference to Figures 3A and 3B and also with reference to Figures 4A and 4B.
HLR Database 20
As illustrated with reference to Figure 1 , a cellular communication network 14 has a HLR database 20 of a mobile switching center (MSC) 1 9 of a cellular communication network that maintains a GPS location data 27C of a mobile handset 1 2. The GPS location data 27C is maintained in the HLR database 20 with reference to a mobile identification number (MIN) 27A and an electronic serial number (ESN) 27B. The HLR database 20 may be part of the MSC 19. Alternatively, the
HLR database 20 may operate independently of the MSC 1 9 and serve the MSC 19 as well as other applications. On request, the HLR database 20 sends the GPS location data of the handsets to an application. These applications may include an application that is resident and operating in the MSC 1 9 itself or the application may be resident and operating in an entity outside of the MSC 19. These applications may include commercial applications that have been contracted for between the commercial and government entities and the cellular network carrier companies.
Mobile Switching Center (MSC) 19 Logic 80
As illustrated with reference to Figure 4C, the MSC 1 9 of the network
14 has MSC logic 80. Logic 80 receives and processes an R-R record 27 from the handset 12 that contains GPS location data 27C and stores GPS location data 27C in the HLR database 20. Logic 80 has the following functions. Function 81 receives R-R signal record 27 from handsets 12 operating in the wireless network. Function 82 processes the R-R signal record from the handset. Function 83 extracts ESN & MIN data from the R-R record and saves in the HLR database. Function 84 extracts handset GPS location data from the R-R record and save the handset GPS location data in lat/long in the HLR database. Function 85 saves the identification of the cells which picked up the R-R signal transmission. Logic 80 functions as described above may be performed in any order and not necessarily the order they are shown in Figure 4C. The end result of the logic 80 is that the HLR database has the GPS location data of the handset 12, in addition to the data already present in the HLR database as in prior art.
Efficient device paging logic 90
The functions of the efficient paging logic 90 are illustrated with reference to Figure 5A and 5B.
As illustrated in Figure 5A, the routing logic 90 operates in the MSC 1 9 in conjunction with the HLR database 20 for routing a received incoming call to a called device 1 2. As part of the routing, the logic 90 first pages by sending a page command in the specific cell where the device 12 is located. The specific cell identification has been determined from the device 12 GPS location data in the HLR database 20. The device 12 responds to the page and the call is routed to the device 12 in that specific cell.
As illustrated in Figure 5B, the functions of logic 90 are illustrated. Function 91 processes the incoming call for routing. Function 92 parse the destination number of the called device and Check its presence in the HLR database 20. Function 93, from the HLR database 20, finds the last known cell identifications of the device 12. Function 94 retrieves the GPS Location data of the device 12 from HLR database 20. Function 95 using these data of the last known cell identifications and the current GPS location data in latitude longitude of the device 12 determines the specific cell identification of the device 12. Knowing the device 12's lat/long from the HLR database helps determine the exact and specific cell identification, the device is at the time of the incoming call.
Function 96 send a page command to the specific cell Id. Function 97 waits for page response from the device 1 2. Function 98 sets up call data. Function 99 routes the incoming call to the identified cell towers in the specific cell.
Emergency Responder Logic 100
The wireless network has emergency-responder logic 100 in the MSC
19. The functions of the logic 1 00 are illustrated with the help of Figures 6A, 6B, 6C and 6D.
As illustrated with the help of Figure 6A, the logic 100, as shown by the dotted box has different parts that operate and execute in three different places. The logic 100 operates in (i) as part of the call routing logic 1 00A, (ii) as part of the 91 1 logic 1 00B, (iii) and as logic 100C as part of the emergency responder database 200. As illustrated in Figure 6A, the call routing logic 100A, for a received
91 1 emergency call from the cell phone device 12, parses the caller id and checks for that caller id in the HLR database 20. The logic 100A finds the last known cell area id and retrieves the handset GPS location data from the HLR database 20. The logic 100A then sends the call control to a 91 1 logic 100B. The 91 1 logic 100B may be part of the MSC system by being co-located or may be operative in another location that is accessible by any MSC 1 9 over the Internet.
The 91 1 logic 100B works in conjunction with logic 100C that is interfaced with an Emergency Responder Data and Physical Address database 200. The 91 1 logic 100B receives the latitude longitude data of the calling device 12 and with the help of database 200 maps that location to the nearest ER region. The 91 1 logic 100B also maps the latitude longitude data to the nearest physical address of the device, again using the database 200.
The logic 100C provides for the search logic and may operate as part of the database servers and provides an interface to the data in the database 200 to search and fetch the ER region data and the physical address data of the device corresponding to a latitude longitude value. Such search logic is considered prior art is used in many prior art applications to search a database.
The database 200 may be managed by a different business entity then the wireless carrier. The database 200 may maintain data related to the entire United States and serve a multiple wireless carriers as well as other businesses. The logic 100C serves as an interface between the logic 1 00B and the database 200.
Logic 1 00B based on the latitude longitude data of the handset 12 receives via logic 100C two different data sets identified as data set A and data set B. The data set A provides the ER region that would be responsible for handling this emergency response and its landline contact number for routing the 91 1 call to that landline number. The dataset B provides the actual physical address where the handset 12 is currently located. Logic 100B having received these two data sets A and B format a record and sends the record to the logic 100A. Then the 91 1 logic 100B sends both of these data to the logic 100A. The logic 100A then embeds physical address data in the call and routes the 91 1 call to the Emergency Responder 29 for the ER region and sets up a live call connection between the device and the ER 29.
The features of the database 200 are illustrated with the help of Figure 6B. The database 200 has two different databases 200A and 200B. The database 200A stores the data relate to different ER regions. For each ER region, the database stores regions id, address, telephone, contact, region boundary, map and latitude longitude boundaries. The database 200 is used to map the latitude longitude data of a received 91 1 call to a specific ER region that would respond to the call. The database 200A sends the landline telephone number of the ER region to the logic 90 for it to route the 91 1 call to that landline number.
The database 200B identifies the cities of each ER region of database 200A and the physical addresses present in each of these cities and the latitude longitude of each such address. The database 200B also identifies the other parts of the city such as various landmarks, parks, streets, and Freeways.
The database 200B maps a latitude longitude data of a received 91 1 call to one of these physical addresses.
The database 200 maps the GPS location data to a physical address and, sends a text message with the physical address to the emergency system. The mapping to a physical address from a GPS location data in latitude and longitude dimensions is prior art. The mapping may be done by a tabular look up of the physical addresses that map to the GPS location data.
The Emergency Responder System 29 is illustrated with reference to Figure 6C. What is illustrated is that a incoming 91 1 call is received by a call handling logic and this logic based on the availability of the Stations routes the call to a particular station manned by an agent.
Each station has a display screen and an audio head phone being used by the agent to receive and respond to the 91 1 call. The station displays meta data such as sequence time date and also displays city, telephone and the physical address of the calling device for the 91 1 call. Optionally the 91 1 logic may also support display of if the cell phone is in a vehicle that is in motion.
The other parts of the display provide for operator notes and dialogue and dispatch notes if any. The 91 1 meta and dialogue and dispatch/resolution data is appropriately formatted and simultaneously being sent and being recorded on a tape storage. The audio feed as heard on the headphone also overlays the physical address in addition to displaying on the display screen.
Figure 6D provided a simplified illustration of the different functions of logic 100. Function 1 01 processes the incoming call for routing. Function 1 02 retrieves location data from the HLR database. Function 1 03 converts the latitude longitude data to a physical address. Function 104 creates a text message and sends to the emergency system. Function 1 05 performs a text to speech conversion of the physical address and function 106 embeds the physical address in the voice call as overlaid audio. Function 107 routes the call the emergency system 29.
The emergency responder logic 1 00A in the MSC for a received 91 1 emergency call from the handset 12 retrieves the handset GPS location data 27C from the HLR database 20. The logic 1 00B maps the GPS location data 27C to a physical address. Logic 1 00A then performs a text to speech conversion of the physical address. The technologies that support text to speech conversion are prior art. The logic 1 00A also may have a function that overlays the speech version of the physical address in a routed 91 1 call to the emergency system 29. Efficient Device 12 Power Management Logic 110
The functions of the efficient device power management logic 1 10 are illustrated with reference to Figures 7A and 7B. As illustrated in Figure 7A, the logic 1 10 operates in the MSC 19 for computing the device's 12 optimum signal transmission strength based on the location of the device in a given cell area respective to the distance to the nearest cell telephone towers. Logic 1 10 working in conjunction with the HLR database 1 0 computes the device 12 optimum signal transmission strength for optimizing battery usage of device 12. Logic 1 10 receives R-R signal record 27 from the device 12 and sends the precise signal strength 31 to the device 12 via the wireless network 14.
The logic 1 10 receives an R-R signal transmission from the device, and updates the HLR database with the cell id and the device's GPS location data as had been described earlier with reference to logic 90.
Subsequent to processing the R-R signal as in logic 90, described earlier, the logic 1 10 reads the current GPS location data of the device and computes the device's transmission signal strength for transmission to the nearest cell tower in the cell area and sends that signal strength to the wireless device over the control channel for the device to store in the device.
This approach it is believed is preferable to computing the device signal transmission strength via prior art triangulation techniques that depends upon the MSC 19 receiving signal from the device at least three cell towers at full power and then based on the relative received signal strength at each cell tower and knowing the geographical placement of each cell tower, to compute the device's location in that cell as well as its distance to the nearest cell tower.
The functions of logic 1 10 are illustrated with reference to Figure 7B. As illustrated in Figure 7B, function 1 1 1 receives R-R signal and verifies Id in HLR database 20. Function 1 1 2 saves GPS Location data of the device 12 in the HLR database 20. Function 1 13 reads Cell Identifications of the handset 12 in the database 20. Function 1 14 reads current GPS lat/long of the device 12. Function 1 15 computes exact cell id from the GPS location data. Function 1 16 computes distance of the device 12 to closest cell tower in the specific cell space. Function 1 1 7 sends/transmits a signal strength management command to the handset. The function 1 18 repeats the process if GPS location data of the device 12, in the database has changed signifying movement of the handset 12 relative to the cell towers. The network 14 sends to the handset 1 2 a handset transmission signal strength 31 , based on the distance of the GPS location of the handset 12 from the cell towers in the cell area in lieu of performing a triangulation logic.
A mobile wireless cell phone device, operating as apart of a wireless communication network has a GPS function. A registration request signal transmission management (RRSTM) logic operating in the cell phone device creates a registration-request (R-R) record and embeds a GPS location data of the device in the record in addition to the international mobility equipment identifier (IMEI) data of the device in the record. The logic sends the R-R record with the GPS location data to the wireless network.
The device receives from the network a device transmission signal strength, as computed by the network based on a distance of the GPS location of the device to the cell towers in the cell area, in lieu of the network performing a triangulation logic to compute the location of the device in the cell area. The device stores the received transmission signal strength and uses that data to calibrate the transmission signal strength of an outgoing voice and data transmission to the network to economize on the battery of the device. The device, operating as part of the wireless network, is programmed to include GPS location data of the device as part of a R-R transmission record to the network.
The device operating as part of the wireless network is programmed to update its GPS location data for inclusion in the R-R record and transmit the R-R record when the device detects a physical movement in the device location that exceeds a threshold equal to 1 00 feet from a prior location.
A wireless network operating in conjunction with wireless mobile devices, has a mobile switching center (MSC) with a home location record (HLR) database that stores subscriber Id data of cell phone devices that are subscribed to and are operating in the network. The network receives and processes a R-R record from the cell phone devices, the records contains a GPS location data of the devices and the network stores the GPS location data of the devices in the HLR database.
The network sends to the device, a handset transmission signal strength, as computed by the network based on the distance of the GPS location of the handset from the cell towers in the cell area, in lieu of performing a triangulation logic.
The MSC for routing a received call into the network from a calling telephone device to a called cell phone device, pages the called device only in the specific cell location that is mapped from the GPS location data of the device in the HLR database, in lieu of paging all the surrounding cells from a last known cell location of the cell phone device.
A cellular communication network has a HLR database of a mobile switching center (MSC) of a cellular communication network that maintains a GPS location data of a mobile cell phone device. The GPS location data is maintained in the HLR database with reference to a mobile identification number (MIN) and a electronic serial number (ESN). The HLR database, on request received by the network, sends the GPS location data of the device with the device identifier to a system hosting an application. The application may include an application that is resident and operating in the MSC itself or the application may be resident and operating in a system by an entity outside of the MSC. A cellular communication network based emergency response system, has a mobile switching center (MSC) of a cellular communication network that maintains, in an home location record (HLR) database, a GPS location data of a mobile cell phone device, for devices that are operating in the network. The MSC has an interface to an emergency response (ER) system. The MSC for a received 91 1 emergency call from a wireless device retrieves the device's GPS location data from the HLR database and sends to the ER system over the interface. An emergency response logic in the ER system maps the received
GPS location data to (i) an ER region contact data from a pre-stored ER region contact database and (ii) maps the GPS location data to a physical address of the device. The logic creates and sends a record with the ER region contact data and the device's physical address data to the MSC over the interface. The MSC receives the record and routs the 91 1 call to the ER region contact landline. The logic embeds a text/voice message with the physical address of the device or sends a separate text message record.
The MSC for a received 91 1 emergency call from a device retrieves the device's GPS location data from the HLR database and routs the call with the location data to an ER system.
An emergency responder logic in the ER system, maps the received GPS location data to (i) an ER region contact data and (ii) to a physical address of the device. The logic routs the call to a landline number of the ER region and embeds a text message with the physical address of the handset to the ER region.
An emergency responder logic in the MSC for a received 91 1 emergency call from the device retrieves the device's GPS location data, maps to a physical address and performs a text to speech conversion of the physical address and embeds the physical address in a routed 91 1 call to the emergency system. An emergency response system for a wireless network has a logic that is operable in a server of the emergency response system that receives a lat/long data of a received 91 1 call, of a cell phone device operating in the wireless network, from a mobile switching center of the wireless network. The logic interfaces with an ER database system, the ER database system maps the lat/long data to a physical address and the logic retrieves the device's physical address from the database.
The logic sends the physical address data to the mobile switching center.
The ER database system also sends to the logic the ER region where the device is located and the landline number of the ER region. The logic sends both the device's physical address and the ER region landline number to the mobile switching center for the mobile switching center, thereby the mobile switching center is able to route the 91 1 emergency call to the specific ER region where the device is located as well as the physical address of the device. The ER database system stores the cities in each of the ER regions and the physical addresses in each city along with their lat/long data. The ER database system stores ER region details including address and landline contact numbers. The ER database system stores for each of the cities in each of the ER regions, the landmarks including parks, highways, libraries, points of interest and their physical addresses along with their lat/long data.
Method of Operation
As illustrated with reference to Figure 8, a method for enhancing the efficiency of a cellular communication network has the following steps where all the steps may not be used or used in the order specified.
At step 1 20, maintaining in a mobile switching center (MSC) of a cellular communication network, a GPS location data of a mobile handset, referenced by a mobile identification number (MIN) and an electronic serial number (ESN), in addition to a geographic cell number, in an HLR database for the handsets, operating in the network.
At step 1 22, retrieving by emergency responder logic in the MSC, for a received 91 1 emergency call, the GPS location data of the handset, from the HLR database, and converting the GPS physical data to a physical address, and sending a text message with the physical address to an emergency response system.
At step 1 24, retrieving by the emergency responder logic in the MSC, for a received 91 1 emergency call, the GPS location data of the handset from the HLR database, and converting the GPS location data to a physical address, performing a text to speech conversion of the physical address and embedding in the voice call before routing the call to the emergency response system.
At step 1 26, routing by the MSC, a received call, by paging a handset only in the cell location identified by the GPS location data.
At step 1 28, sending by the network to the handset, a handset transmission signal strength, based on the distance of the GPS location of the handset from the cell towers in the cell area in lieu of performing a
triangulation logic.
At step 1 30, receiving and processing by the network an R-R record that contains GPS location data and stores GPS location data in the HLR database.
At step 1 32, programming the handset operating as part of the network to include GPS location data as part of an R-R transmission record.
At step 1 34, programming the handset, operating as part of the network, to update its GPS location data when the handset has moved more than 100 feet.
Further detailed method steps are provided as follows.
A method for a mobile wireless cell phone device, operating as apart of a wireless communication network has the following steps, where all the steps may not be used or used in the order specified:
a. having by the cell phone device a GPS function; b. creating by a registration request signal transmission
management (RRSTM) logic, operating in the cell phone device, a
registration-request (R-R) record and embedding a GPS location data of the device in the record in addition to a international mobility equipment identifier (IMEI) data of the cell phone device in the record;
c. sending by the logic the R-R record with the GPS location data to the wireless network.
d. receiving by the device from the network a device transmission signal strength, as computed by the network based on a distance of the GPS location of the device to the cell towers in the cell area, in lieu of the network performing a triangulation logic to compute the location of the device.
d. storing by the device the received transmission signal strength and using that data to calibrate the transmission signal strength of an outgoing voice and data transmission to the network and thus economize on the battery of the device.
e. programming the device, operating as part of the wireless network, to include GPS location data as part of a R-R transmission record. f. programming the device operating as part of the wireless network to update its GPS location data for inclusion in the R-R record and send the R-R record when the device detects a physical movement in the device's location that exceeds 100 feet from a prior location.
A method for a wireless network operating in conjunction with mobile wireless devices has the following steps where all the steps may not be used or used in the order specified:
a. having by the wireless network a mobile switching center (MSC) with a home location record (HLR) database that stores subscriber Id data of cell phone devices that are subscribed to and are operating in the network; b. receiving and processing by the network a R-R record from the cell phone devices, the records containing a GPS location data of the devices and the network storing the GPS location data of the devices in the HLR database.
c. sending by the network to the device, a device transmission signal strength, as computed by the network based on the distance of the GPS location of the device from the cell towers in the cell area, in lieu of performing a triangulation logic.
d. paging by the MSC, for routing a received call into the network from a calling telephone device to a called cell phone device, only the called device in the specific cell location that is mapped from the GPS location data of the device in the HLR database, in lieu of paging all the surrounding cells from a last known cell location of the cell phone device.
A method for cellular communication network based emergency response system, has the following steps where all the steps may not be used or used in the order specified:
a. maintaining by a mobile switching center (MSC) of a cellular communication network, in an home location record (HLR) database, a GPS location data of a mobile cell phone device, for devices that are operating in the network;
b. interfacing the MSC to an emergency response (ER) system; c. retrieving the device's GPS location data from the HLR database by the MSC for a received 91 1 emergency call for the device and sending to the ER system over the interface.
d. mapping by an emergency responder logic in the ER system, the received GPS location data to (i) an ER region contact data and (ii) to a physical address of the device.
e. creating by the logic and sending a record with the ER region contact data and the device's physical address data to the MSC over the interface;
f. receiving by the MSC the record and routing the 91 1 call to the ER region contact landline;
g. embedding by the logic a text/voice message with the physical address of the device or sending a separate text message record.
h. mapping by an emergency responder logic in the ER system, mapping the received GPS location data to (i) an ER region contact data and (ii) to a physical address of the handset; i. routing by the logic the call to a landline number of the ER region and embeds a text message with the physical address of the device to the ER region.
j. retrieving the device's GPS location data by an emergency responder logic in the MSC for a received 91 1 emergency call from the handset, mapping to a physical address and performing a text to speech conversion of the physical address and embedding the physical address in a routed 91 1 call to the emergency system. A method of a cellular communication network operation has the following steps where all the steps may not be used or used in the order specified:
a. maintaining in a mobile switching center (MSC) of a cellular communication network, a GPS location data of a mobile handset, referenced by a mobile identification number (MIN) and an electronic serial number (ESN), in addition to a geographic cell number, in an HLR database for the cell phone devices, operating in the network.
b. retrieving by an emergency responder logic in the MSC, for a received 91 1 emergency call, the GPS location data of the device, from the HLR database, and converting the GPS physical data to a physical address, and sending a text message with the physical address to an emergency response system.
c. retrieving by the emergency responder logic in the MSC, for a received 91 1 emergency call, the GPS location data of the device from the HLR database, and converting the GPS location data to a physical address, performing a text to speech conversion of the physical address and embedding in the voice call before routing the call to the emergency response system. In summary, a cellular communication network with a mobile switching center (MSC) of a cellular communication network maintains a GPS location data of a mobile handset referenced by a mobile identification number (MIN) and an electronic serial number (ESN) in addition to a geographic cell number in an HLR database for handsets operating in the network. The network uses the GPS location data of the handsets in its network for different purposes, these may include, (i) efficient paging for routing incoming calls, (ii) efficient location data response to emergency responders, and (iii) more efficient management of battery in the handsets.
While the particular invention, as illustrated herein and disclosed in detail is fully capable of obtaining the objective and providing the advantages herein before stated, it is to be understood that it is merely illustrative of the presently preferred embodiments of the invention and that no limitations are intended to the details of construction or design herein shown other than as described in the appended claims.

Claims

I CLAIM:
1 . A mobile wireless cell phone device, operating as apart of a wireless communication network, comprising:
a. the cell phone device has a GPS function;
b. a registration request signal transmission management
(RRSTM) logic operating in the cell phone device creates a registration- request (R-R) record and embeds a GPS location data of the device in the record in addition to the international mobility equipment identifier (IMEI) data of the device in the record;
c. the logic sends the R-R record with the GPS location data to the wireless network.
2. The device as in claim 1 , comprising:
the device receives from the network a device transmission signal strength, as computed by the network based on a distance of the GPS location of the device to the cell towers in the cell area, in lieu of the network performing a triangulation logic to compute the location of the device in the cell area.
3. The device as in claim 2, comprising:
the device stores the received transmission signal strength and uses that data to calibrate the transmission signal strength of an outgoing voice and data transmission to the network to economize on the battery of the device.
4. The device as in claim 1 , comprising:
the device, operating as part of the wireless network, is programmed to include GPS location data of the device as part of a R-R transmission record to the network.
5. The network as in claim 1 , comprising:
the device operating as part of the wireless network is programmed to update its GPS location data for inclusion in the R-R record and transmit the R-R record when the device detects a physical movement in the device location that exceeds a threshold equal to 1 00 feet from a prior location.
6. A method for a mobile wireless cell phone device, operating as apart of a wireless communication network, comprising the steps of:
a. having by the cell phone device a GPS function;
b. creating by a registration request signal transmission
management (RRSTM) logic, operating in the cell phone device, a
registration-request (R-R) record and embedding a GPS location data of the device in the record in addition to a international mobility equipment identifier (IMEI) data of the cell phone device in the record;
c. sending by the logic the R-R record with the GPS location data to the wireless network.
7. The method as in claim 6, comprising the steps of:
receiving by the device from the network a device transmission signal strength, as computed by the network based on a distance of the GPS location of the device to the cell towers in the cell area, in lieu of the network performing a triangulation logic to compute the location of the device.
8. The method as in claim 7, comprising the steps of:
storing by the device the received transmission signal strength and using that data to calibrate the transmission signal strength of an outgoing voice and data transmission to the network and thus economize on the battery of the device.
9. The method as in claim 6, comprising the steps of:
programming the device, operating as part of the wireless network, to include GPS location data as part of a R-R transmission record.
10. The device as in claim 6, comprising the steps of:
programming the device operating as part of the wireless network to update its GPS location data for inclusion in the R-R record and send the R-R record when the device detects a physical movement in the device's location that exceeds 100 feet from a prior location.
1 1 . A wireless network operating in conjunction with wireless mobile devices, comprising:
a. the wireless network has a mobile switching center (MSC) with a home location record (HLR) database that stores subscriber Id data of cell phone devices that are subscribed to and are operating in the network;
b. the network receives and processes a R-R record from the cell phone devices, the records contains a GPS location data of the devices and the network stores the GPS location data of the devices in the HLR database.
12. The a wireless network, as in claim 1 1 , comprising:
the network sends to the device, a handset transmission signal strength, as computed by the network based on the distance of the GPS location of the handset from the cell towers in the cell area, in lieu of performing a triangulation logic.
13. The network as in claim 1 1 , comprising:
the MSC for routing a received call into the network from a calling telephone device to a called cell phone device, pages the called device only in the specific cell location that is mapped from the GPS location data of the device in the HLR database, in lieu of paging all the surrounding cells from a last known cell location of the cell phone device.
14. A method for a wireless network operating in conjunction with mobile wireless devices, comprising the steps of:
a. having by the wireless network a mobile switching center (MSC) with a home location record (HLR) database that stores subscriber Id data of cell phone devices that are subscribed to and are operating in the network; b. receiving and processing by the network a R-R record from the cell phone devices, the records containing a GPS location data of the devices and the network storing the GPS location data of the devices in the HLR database.
15. The method for the wireless network, as in claim 14, comprising the steps of:
sending by the network to the device, a device transmission signal strength, as computed by the network based on the distance of the GPS location of the device from the cell towers in the cell area, in lieu of performing a triangulation logic.
16. The method of network as in claim 14, comprising the steps of:
paging by the MSC, for routing a received call into the network from a calling telephone device to a called cell phone device, only the called device in the specific cell location that is mapped from the GPS location data of the device in the HLR database, in lieu of paging all the surrounding cells from a last known cell location of the cell phone device.
17. A cellular communication network, comprising:
a HLR database of a mobile switching center (MSC) of a cellular communication network that maintains a GPS location data of a mobile cell phone device.
18. The cellular communication network as in claim 17, comprising:
the GPS location data is maintained in the HLR database with reference to a mobile identification number (MIN) and a electronic serial number (ESN).
19. The cellular communication network as in claim 17, comprising:
the HLR database, on request received by the network, sends the GPS location data of the device with the device identifier to a system hosting an application.
20. The cellular communication network as in claim 19, comprising:
the application may include an application that is resident and operating in the MSC itself or the application may be resident and operating in a system by an entity outside of the MSC.
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Families Citing this family (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US10516780B2 (en) * 2012-09-10 2019-12-24 Tools/400 Inc. Emergency 9-1-1 portal and application
US9049584B2 (en) 2013-01-24 2015-06-02 Ford Global Technologies, Llc Method and system for transmitting data using automated voice when data transmission fails during an emergency call
US9357369B2 (en) 2014-07-03 2016-05-31 At&T Intellectual Property I, L.P. Reducing provider costs related to E911 service
KR20160012576A (en) * 2014-07-24 2016-02-03 삼성전자주식회사 Operating Method and Device for disaster information
JP6648152B2 (en) * 2015-10-27 2020-02-14 株式会社タップアラウンド Information sharing support server, information sharing support system, and information sharing support method
US9918211B2 (en) * 2016-06-13 2018-03-13 At&T Mobility Ii Llc Mobile emergency response network
JP6649191B2 (en) * 2016-06-29 2020-02-19 クラリオン株式会社 In-vehicle processing unit
CN113726030A (en) * 2021-08-25 2021-11-30 上海联净电子科技有限公司 Millimeter wave wireless charging management method, device, server, system and medium

Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20020071408A1 (en) * 2000-09-12 2002-06-13 Shinsuke Ogawa CDMA wireless transmission apparatus, CDMA wireless transmitter-receiver system and transmission power control method of the CDMA wireless transmission apparatus
US7076256B1 (en) * 2001-04-16 2006-07-11 Sirf Technology, Inc. Method and apparatus for transmitting position data using control channels in wireless networks
US20080133336A1 (en) * 2006-06-01 2008-06-05 Altman Samuel H Location-Based Advertising Message Serving For Mobile Communication Devices
US20080261571A1 (en) * 2000-12-19 2008-10-23 Zellner Samuel N Location blocking service from a wireless service provider
US7991393B1 (en) * 2005-02-10 2011-08-02 Sprint Communications Company L.P. Wireline terminal accessing mobile telephone services

Family Cites Families (15)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US7783299B2 (en) * 1999-01-08 2010-08-24 Trueposition, Inc. Advanced triggers for location-based service applications in a wireless location system
US6845246B1 (en) * 2000-06-15 2005-01-18 Nortel Networks Limited Location based power control for mobile communications systems
US6907254B1 (en) * 2001-03-08 2005-06-14 Cisco Technology, Inc. Method and apparatus for controlling a quiet zone for wireless units
US7260415B1 (en) * 2001-05-31 2007-08-21 Sprint Spectrum L.P. Method and system for location-based power control in wireless communications
US7177623B2 (en) * 2003-07-02 2007-02-13 The United States Of America As Represented By The Secretary Of The Army Localized cellular awareness and tracking of emergencies
US20070293186A1 (en) * 2004-02-11 2007-12-20 Ctl Analyzers, Llc Systems and Methods for a Personal Safety Device
JP4532298B2 (en) * 2005-01-28 2010-08-25 株式会社エヌ・ティ・ティ・ドコモ POSITION INFORMATION INTEGRATED MANAGEMENT DEVICE AND POSITION INFORMATION INTEGRATED MANAGEMENT METHOD
WO2006081656A1 (en) * 2005-02-03 2006-08-10 Blueslice Networks Inc. Dynamic identity association within a wireless network
US8204520B2 (en) * 2006-06-02 2012-06-19 West Corporation System and method for routing short message service special number messages to local special number answering points
US7974645B2 (en) * 2006-08-30 2011-07-05 At&T Mobility Ii Llc Mobile registration using a service area identifier or plurality of service area identifiers
US8705442B2 (en) * 2007-11-15 2014-04-22 Ubeeairwalk, Inc. System, method, and computer-readable medium for mobile station authentication and registration via an IP-femtocell
US8761764B2 (en) * 2008-08-01 2014-06-24 Tekelec, Inc. Systems, methods, and computer readable media for triggerless mobile location-based routing / screening
US8332095B2 (en) * 2008-12-08 2012-12-11 Hembury Christine M Computer controlled system and method for ensuring all vehicles entering and/or in an area are GPS location registered
US8199001B2 (en) * 2009-05-12 2012-06-12 Qualcomm Incorporated Dynamic reporting scheme for location based services
US8532687B2 (en) * 2009-12-08 2013-09-10 Apple Inc. Methods for geographic optimization of cellular telephone transmit power settings

Patent Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20020071408A1 (en) * 2000-09-12 2002-06-13 Shinsuke Ogawa CDMA wireless transmission apparatus, CDMA wireless transmitter-receiver system and transmission power control method of the CDMA wireless transmission apparatus
US20080261571A1 (en) * 2000-12-19 2008-10-23 Zellner Samuel N Location blocking service from a wireless service provider
US7076256B1 (en) * 2001-04-16 2006-07-11 Sirf Technology, Inc. Method and apparatus for transmitting position data using control channels in wireless networks
US7991393B1 (en) * 2005-02-10 2011-08-02 Sprint Communications Company L.P. Wireline terminal accessing mobile telephone services
US20080133336A1 (en) * 2006-06-01 2008-06-05 Altman Samuel H Location-Based Advertising Message Serving For Mobile Communication Devices

Non-Patent Citations (1)

* Cited by examiner, † Cited by third party
Title
See also references of EP2829052A4 *

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EP2829052A4 (en) 2015-10-21
CN104205794B (en) 2018-09-11
CN104205794A (en) 2014-12-10
US20130244611A1 (en) 2013-09-19
CA2867664A1 (en) 2013-09-26
EP2829052B1 (en) 2019-10-23
US8897826B2 (en) 2014-11-25
EP2829052A1 (en) 2015-01-28

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