Abstract: An automated telecommunications system includes a first system that receives audio frequency signals such as PSTN-compatible, voice over IP, or high definition voice, decodes and interprets said incoming signals according to the type and format, and transmits digital messages to a second system over a software defined wide area network (SDWAN). Said second system receives and interprets digital messages incoming from the first system, encodes and regenerates outgoing audio frequency signals. The system may be bi-directional and operate over a software defined wide area network, such as an IP based wireless or wired data network. The functionality of said first and second systems may be combined at a single location and interface with a conventional PSTN compatible VoIP system or High Definition Voice system at either or both ends and allow PSTN, conventional VoIP and High Definition Voice communications to share the same packet data stream over a SDWAN connection.

Abstract: An automated telecommunications system includes a first system that receives audio frequency signals such as PSTN-compatible, voice over IP, or high definition voice, decodes and interprets said incoming signals according to the type and format, and transmits digital messages to a second system over a software defined wide area network (SDWAN). Said second system receives and interprets digital messages incoming from the first system, encodes and regenerates outgoing audio frequency signals. The system may be bi-directional and operate over a software defined wide area network, such as an IP based wireless or wired data network. The functionality of said first and second systems may be combined at a single location and interface with a conventional PSTN compatible VoIP system or High Definition Voice system at either or both ends and allow PSTN, conventional VoIP and High Definition Voice communications to share the same packet data stream over a SDWAN connection.

Abstract: An automated telecommunications system includes a first system operable to receive PSTN compatible audio frequency signals, to decode and interpret said incoming signals according to the type of call and call format, and transmit digital messages to a second system over a packet data network. Said second system receives and interprets digital messages incoming from the first system, encodes and regenerate outgoing audio frequency signals. The system may be bidirectional and operate over a packet based data network, such as for example an IP based wireless data network. The functionality of said first and second systems may be combined at a single location and interface with a VoIP system at either or both ends and allows PSTN and VoIP communications to share the same packet data stream over a wireless network connection.

Abstract: An automated telecommunications system includes a first system operable to receive PSTN compatible audio frequency signals, to decode and interpret said incoming signals according to the type of call and call format, and transmit digital messages to a second system over a packet data network. Said second system receives and interprets digital messages incoming from the first system, encodes and regenerate outgoing audio frequency signals. The system may be bi-directional and operate over a packet based data network, such as for example an IP based wireless data network. The functionality of said first and second systems may be combined at a single location and interface with a VoIP system at either or both ends and allows PSTN and VoIP communications to share the same packet data stream over a wireless network connection.

Abstract: An automated telecommunications system includes a first system operable to receive PSTN compatible audio frequency signals, to decode and interpret said incoming signals according to the message format and a modem protocol being used, and transmit digital messages to a second system over a packet data network. Said second system receives and interprets digital messages incoming from the first system, encodes and regenerate outgoing audio frequency signals. The system may be bi-directional and operate over a packet based data network, such as for example an Internet protocol (IP) based network, a satellite based network, or an IP based cable or wireless network. The functionality of said first and second systems may be combined at a single location and operate with a VoIP network to allow modem signals to pass across the VoIP system.

Abstract: An automated telecommunications system includes a first system operable to receive PSTN compatible audio frequency signals, to decode and interpret said incoming signals according to the message format and a modem protocol being used, and transmit digital messages to a second system over a packet data network. Said second system receives and interprets digital messages incoming from the first system, encodes and regenerate outgoing audio frequency signals. The system may be bi-directional and operate over a packet based data network, such as for example an Internet protocol (IP) based network, a satellite based network, or an IP based cable or wireless network. The functionality of said first and second systems may be combined at a single location and operate with a VoIP network to allow modem signals to pass across the VoIP system.

Abstract: An automated telecommunications backup system includes a first system operable to monitor a primary time division multiplexing (TDM) link on a TDM network for a failure condition and a second system operable to back up at least a portion of the telecommunications traffic of the TDM link over a backup network. The backup network may be a packet based network, an Internet protocol (IP) based network, a satellite based network, or an IP based system over a satellite network. The first system may continuously monitor the primary TDM link and switch the functionality thereof into circuit with the TDM link upon the detection of the failure condition. The second system may compress the telecommunications traffic of the TDM link to transmit a pre-designated number of time slots thereof.

Abstract: A patch panel apparatus, system, method and computer program product for patch cord path tracing is provided.

Abstract: An adaptive telecommunications system for transporting communication traffic over a network comprising a means for transmitting communication traffic between a plurality of devices through a network, monitoring the communication traffic between the plurality of devices, and a adaptively changing the mode of operation either before and/or during a call, based on at least one of instantaneous network changes, connection type characteristics, and type of communication traffic. The devices attached to the network may consist of, for example, a fax machine, phone, mobile phone, public branch network exchange, a computer, or a switch. The traffic traveling across the system, voice, fax, or data, for example, may be compressed and/or restricted based on the type of traffic. The system may fully replace the existing PSTN circuits or may be used for overflow when the existing PSTN circuits are at near or full capacity.

Abstract: An automated telecommunications backup system includes a first system operable to monitor a primary time division multiplexing (TDM) link on a TDM network for a failure condition and a second system operable to back up at least a portion of the telecommunications traffic of the TDM link over a backup network. The backup network may be a packet based network, an Internet protocol (IP) based network, a satellite based network, or an IP based system over a satellite network. The first system may continuously monitor the primary TDM link and switch the functionality thereof into circuit with the TDM link upon the detection of the failure condition. The second system may compress the telecommunications traffic of the TDM link to transmit a pre-designated number of time slots thereof.

Abstract: A patch panel apparatus, system, method and computer program product for patch cord path tracing is provided.