Telephonic communications – Emergency or alarm communications – Central office responsive to emergency call or alarm
Reexamination Certificate
2002-10-21
2004-08-03
Ramakrishnaiah, Melur (Department: 2643)
Telephonic communications
Emergency or alarm communications
Central office responsive to emergency call or alarm
C379S037000, C379S042000
Reexamination Certificate
active
06771742
ABSTRACT:
FIELD OF THE INVENTION
This invention relates to emergency telephone services (9-1-1 services). In particular, the present invention relates to the routing of emergency services calls from call centers to public safety answering points, and to the provision of data in connection with such calls.
BACKGROUND OF THE INVENTION
Abbreviated number systems have been provided as part of the public switched telephone network to provide callers with a convenient, easily remembered number that can be used to access important services. Most prominently, the 9-1-1 system in the United States was developed for handling emergency service calls. Abbreviated number systems similar to the 9-1-1 system in use in the United States are in place in other countries for handling emergency service calls. The abbreviated number system established in Canada is the foreign system most similar to the system established in the United States. In addition, there are other abbreviated number calling systems in place in the United States and other countries for such purposes as handling municipal information and services calls (3-1-1). All of these special, or abbreviated number call systems that have geographic-based content suffer from similar shortcomings in their abilities to automatically place incoming calls to an action-response facility geographically proximate to the locus of the caller. In particular, calls must originate from within the serving area of telephone company switching equipment interconnected to the appropriate public safety answering point. Accordingly, calls handled through intermediary service providers, such as alarm companies and telematics service providers cannot benefit from the automated routing and information delivery features available in connection with many conventional abbreviated number systems.
In a basic emergency services notification and dispatch system (or 9-1-1 system), a telephone company end office (also known as a “central office” or a “Class 5 office”) is programmed to route all emergency calls (e.g., all 9-1-1 calls) to a single destination. The single destination is termed a public safety answering point (PSAP). In such an arrangement, all telephones served by the central office have their 9-1-1 calls completed to the PSAP. However, the areas served by respective telephone company central offices usually do not line up with the political jurisdictions that determine the boundaries for which a PSAP may be responsible. That is, a municipal fire department or police department may geographically include an area outside the area served by the central office, a condition known as underlap. Likewise, the municipal fire or police department may encompass an area of responsibility that is less expansive than the area served by the central office, a situation known as overlap. Further, the original basic 9-1-1 systems did not provide any identification of the caller. Accordingly, the PSAP human operator must obtain such information verbally over the line after the call is connected. In addition, basic 9-1-1 systems cannot support interconnection to other telecommunication providers such as independent telephone service companies, alternate local exchange carriers (ALECs), or wireless carriers.
Automatic number identification (ANI) is a feature for 9-1-1 services that was developed to allow the caller's telephone number to be delivered with the call and displayed at the PSAP. This feature is useful for identifying the caller and, if the caller cannot communicate, for callback. Using subscriber information stored by telephone companies based upon telephone number, the caller's name and address can be provided as well as part of automatic location identification (ALI) databases. In particular, the PSAP can query the ALI database using the caller's number provided by the ANI feature to ascertain name and address information. However, such systems are ineffective where several telephone company central offices serve a PSAP.
In order to handle the situation of multiple central offices serving a single PSAP, the 9-1-1 tandem was developed. The tandem is a telephone company switch that provides an intermediate concentration and switching point. In particular, trunks from central offices are concentrated at a tandem office (a 9-1-1 tandem) from which a single trunk group serves a given PSAP. Often a 9-1-1 tandem comprises an otherwise common Class 5 telephone system end office (EO), with added software to configure it for 9-1-1 operations. Such concentration of trunks reduces the size and cost of PSAP equipment.
More recently, enhanced 9-1-1 (E9-1-1) has become available. Some of the features of E9-1-1 include selective routing, ANI, ALI, selective transfer and fixed transfer. However, as with a basic 9-1-1 system, a 9-1-1 call must originate within the serving area of the E9-1-1 tandem.
It would be desirable to provide for the routing of requests for emergency services to an appropriate public safety answering point even if such requests are placed through central call centers. Such call centers include alarm monitoring centers, automatic collision notification centers, and other centers that may receive requests for emergency services that originate from a location that is removed from the location of the call center.
Alarm companies typically provide for monitoring of subscriber premises from a central monitoring station. In a typical alarm implementation, a security system communicator is placed in the home or business. When an alarm is detected, the communicator seizes the telephone line from the telephone instruments, dials a number in the alarm company monitoring station, transmits to the receiver in the monitoring station information regarding the client's account information and the alarm event, and releases the telephone line. The alarm company may then call the subscriber number to weed out false alarms. If a valid alarm is ascertained, the alarm company looks up the telephone number for the emergency service provider that serves the client's area and dials a 10 digit number to report the incident. The alarm company then verbally passes any information it has that may assist the call taker. In addition to stationary premises alarms, new types of personal alarms are being introduced that may be worn on the person and use wireless communications to alert the alarm company.
Automatic collision notification (ACN) centers receive calls placed from vehicles requiring assistance. For example, in the event of an accident, equipment in an automobile or an occupant of the automobile may call the ACN center using a wireless link, such as a cellular telephone system, rather than a public emergency service number, and pass information related to the accident to the ACN center. This data may be uploaded from a unit in the automobile to a database at the call center. The operator at the ACN center then attempts to determine the appropriate emergency service agency to respond to the request, and calls that agency using a 10 digit number. The operator verbally communicates any information he/she has about the caller's location and situation to the agency personnel. This scenario is complicated in that, like alarm monitoring centers, ACN call centers may handle calls from callers that may be located anywhere in the country or the world.
Another type of centralized call center may be associated with requests for emergency services originating from communication devices utilizing a voice over Internet protocol (VoIP) connection. An IP private branch exchange (PBX) typically serves this type of connection. The actual location of the caller is unknown at the time that a call is initiated. Accordingly, for proper routing of the VoIP phone connection, the location of the caller must be determined. Current solutions require a VoIP user to dial a special number for emergency service, which will connect them to an attendant at a third party emergency service provider call center that will in turn call the appropriate emergency service number. Dialing of 9-1-1 by
Mathis Ronald W.
McCalmont Patti L.
Schmidt Peter R.
Sherry Robert A.
Intrado Inc.
Ramakrishnaiah Melur
Sheridan & Ross P.C.
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