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Super-Charged network or Super-Charger network, is a telecommunications term that refers to a particular standardized implementation of a 3GPP 3G telecommunications network. 3GPP has standardized Super-Charger networks in TS 23.116, the Super-Charger technical realization, and defines a Super-Charged network as a "UMTS network in which the Super-Charger mechanism is being used to optimise mobility management signalling." [1]
A regular UMTS network can be retrofitted to provide Super-Charger support by providing Super-Charger support within each network entity. Once a network entity has been modified to support Super-Charger functionality it is referred to as a Super-Charged network entity. For example, a Home Location Register (HLR) with Super-Charger functionality would be referred to as a Super-Charged HLR. [1]
In a regular telecommunication network environment, transferring from a previous network to a serving network (i.e. handing off) uses a substantial amount of signalling traffic. For 3GPP networks, when the user equipment (UE) enters the serving network from the previous network, the UE triggers a "Location Update" request to be sent from the UE to the serving network's visitor location register (VLR). The serving network's VLR passes the Location Update request to the UE's home network's HLR. The HLR then performs two operations: 1) sends a "Cancel Location" message to the previous network's VLR, in an effort to remove the subscriber's data from the previous network, and 2) sends an Insert Subscriber Data message to the serving network's VLR, in an effort to add the subscriber's information to the serving network. After acknowledgments from the respective VLRs have been received for these steps, the HLR will send a Location Update confirmation back to the serving network, which forwards it to the UE, thereby informing the UE that the location update processing is complete by all parties involved. [1]
However, when the UE jumps back and forth between the previous and serving networks, the signalling overhead resulting from the frequent Location Update messages is substantial and the resulting traffic is burdensome to the network. [1]
A solution was implemented with the Super-Charger realization in an effort to reduce telecommunications signaling traffic. The general concept behind the Super-Charger network is that the location registers in any visiting network do not delete subscriber data even after a subscriber leaves their control, by, for instance, exiting their coverage area. This allows the UE to jump back and forth between the networks and, since the previous network, serving network, and home network's HLR are Super-Charged and maintaining copies of the subscriber information, the HLR does not have to re-send the subscriber information or Cancel Location request messages. [1] [2]
Outdated subscriber information is a concern if the UE does not re-enter the previous visiting network after an extended period of time. To prevent out dating of the subscriber data, an age indicator is associated with the subscriber information maintained in all location registers. If the HLR deems that the age indicator in a visiting network is too old, or determines the subscriber's information has changed since the visiting network last received the information, the HLR will send the subscriber data like normal. [1] [2]
If the visiting networks are maintaining subscriber information for all subscribers that enter and then subsequently exit their coverage area, the visiting networks will have to maintain a significant amount of subscriber information. Therefore, visiting networks should implement database maintenance measures to ensure outdated and unused subscriber information is removed. This will free up memory for new subscriber information. [1] [2]
After an HLR receives an Update Location request from a visiting network, the HLR must be able to identify whether the new and old visiting networks are Super-Charged or not. If the old visiting network is Super-Charged, the HLR does not send a Cancel Location message. If the old visiting network is not Super-Charged, the HLR sends the Cancel Location message. If the new visiting network is Super-Charged and has previously received the subscriber information and it is not outdated, the HLR does not send an Insert Subscriber Data request. Otherwise, the HLR will send the Insert Subscriber Data request. [1]
Further signalling traffic reductions can occur by not sending acknowledgements. Typically, when a HLR instructs a subscriber purge (via a Cancel Location message) to a visiting network, the visiting network purges the subscriber information and sends an acknowledgment back to the HLR. The networks can further cut back on signalling traffic by not returning an acknowledgment, and just having the HLR assume the purge was completed. However, since Super-Charged visiting networks can purge subscriber data on their own due to periodic database cleanups, the visiting network register must identify whether the subscriber purge is externally instructed. If the purge is externally instructed, no acknowledgment is returned. If the purge is internally instructed, an acknowledgment is sent to the HLR. [3]
Short Message Service, commonly abbreviated as SMS, is a text messaging service component of most telephone, Internet and mobile device systems. It uses standardized communication protocols that let mobile devices exchange short text messages. An intermediary service can facilitate a text-to-voice conversion to be sent to landlines.
Roaming is a wireless telecommunication term typically used with mobile devices, such as mobile phones. It refers to a mobile phone being used outside the range of its native network and connecting to another available cell network.
Multimedia Messaging Service (MMS) is a standard way to send messages that include multimedia content to and from a mobile phone over a cellular network. Users and providers may refer to such a message as a PXT, a picture message, or a multimedia message. The MMS standard extends the core SMS capability, allowing the exchange of text messages greater than 160 characters in length. Unlike text-only SMS, MMS can deliver a variety of media, including up to forty seconds of video, one image, a slideshow of multiple images, or audio.
The GPRS core network is the central part of the general packet radio service (GPRS) which allows 2G, 3G and WCDMA mobile networks to transmit Internet Protocol (IP) packets to external networks such as the Internet. The GPRS system is an integrated part of the GSM network switching subsystem.
Mobility management is one of the major functions of a GSM or a UMTS network that allows mobile phones to work. The aim of mobility management is to track where the subscribers are, allowing calls, SMS and other mobile phone services to be delivered to them.
Network switching subsystem (NSS) is the component of a GSM system that carries out call out and mobility management functions for mobile phones roaming on the network of base stations. It is owned and deployed by mobile phone operators and allows mobile devices to communicate with each other and telephones in the wider public switched telephone network (PSTN). The architecture contains specific features and functions which are needed because the phones are not fixed in one location.
GSM services are a standard collection of applications and features available over the Global System for Mobile Communications (GSM) to mobile phone subscribers all over the world. The GSM standards are defined by the 3GPP collaboration and implemented in hardware and software by equipment manufacturers and mobile phone operators. The common standard makes it possible to use the same phones with different companies' services, or even roam into different countries. GSM is the world's most dominant mobile phone standard.
The IP Multimedia Subsystem or IP Multimedia Core Network Subsystem (IMS) is a standardised architectural framework for delivering IP multimedia services. Historically, mobile phones have provided voice call services over a circuit-switched-style network, rather than strictly over an IP packet-switched network. Various voice over IP technologies are available on smartphones; IMS provides a standard protocol across vendors.
GPRS Tunnelling Protocol (GTP) is a group of IP-based communications protocols used to carry general packet radio service (GPRS) within GSM, UMTS, LTE and 5G NR radio networks. In 3GPP architectures, GTP and Proxy Mobile IPv6 based interfaces are specified on various interface points.
The Mobile Application Part (MAP) is an SS7 protocol that provides an application layer for the various nodes in GSM and UMTS mobile core networks and GPRS core networks to communicate with each other in order to provide services to users. The Mobile Application Part is the application-layer protocol used to access the Home Location Register, Visitor Location Register, Mobile Switching Center, Equipment Identity Register, Authentication Centre, Short message service center and Serving GPRS Support Node (SGSN).
GSM procedures are sets of steps performed by the GSM network and devices on it in order for the network to function. GSM is a set of standards for cell phone networks established by the European Telecommunications Standards Institute and first used in 1991. Its procedures refers to the steps a GSM network takes to communicate with cell phones and other mobile devices on the network. IMSI attach refers to the procedure used when a mobile device or mobile station joins a GSM network when it turns on and IMSI detach refers to the procedure used to leave or disconnect from a network when the device is turned off.
The Short Message Service is realised by the use of the Mobile Application Part (MAP) of the SS7 protocol, with Short Message protocol elements being transported across the network as fields within the MAP messages. These MAP messages may be transported using "traditional" TDM based signalling, or over IP using SIGTRAN and an appropriate adaptation layer.
CAVE-based Authentication is an access authentication protocol used in CDMA/1xRTT computer network systems.
System Architecture Evolution (SAE) is the core network architecture of mobile communications protocol group 3GPP's LTE wireless communication standard.
Generic Bootstrapping Architecture (GBA) is a technology that enables the authentication of a user. This authentication is possible if the user owns a valid identity on an HLR or on an HSS.
The Um interface is the air interface for the GSM mobile telephone standard. It is the interface between the mobile station (MS) and the Base transceiver station (BTS). It is called Um because it is the mobile analog to the U interface of ISDN. Um is defined in the GSM 04.xx and 05.xx series of specifications. Um can also support GPRS packet-oriented communication.
Insert Subscriber Data is a Subscriber Data Handling procedure in LTE services. This procedure is used to manage the subscription data of subscriber in MME and SGSN over S6a/S6d interface. IDR is invoked by Home Subscriber Server for subscription data handling. IDR is MAP subscriber management service utilized in GSM/UMTS networks, standardized by 3GPP, and defined in the MAP specification, TS 29.002. This service is used to provide specific subscriber data in the following environments: by an HLR to update a VLR, by an HLR to update a SGSN, and by an HSS to update a MME via IWF in an EPS. This service is primarily used by the home subscriber management entity to update the serving subscriber management entity when there is either a change in a subscriber parameter, or upon a location updating of the subscriber.
The Mobile Telephone Switching Office (MTSO) is the mobile equivalent of a PSTN Central Office. The MTSO contains the switching equipment or Mobile Switching Center (MSC) for routing mobile phone calls. It also contains the equipment for controlling the cell sites that are connected to the MSC.
The MMS Architecture is the set of standards used by the Multimedia Messaging Service in mobile networks. The standards are prepared by 3GPP.
IMS is a set of specifications to offer multimedia services through IP protocol. This makes it possible to incorporate all kinds of services, such as voice, multimedia and data, on an accessible platform through any Internet connection.
{{cite web}}: CS1 maint: numeric names: authors list (link) Cellular network standards | |||||||||
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| 0G radio telephones (1946) | |||||||||
| 1G (1979) |
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| 2G (1991) |
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| 2G transitional (2.5G, 2.75G, 2.9G) |
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| 3G (1998) IMT-2000 (2001) |
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| 3G transitional (3.5G, 3.75G, 3.9G) |
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| 4G (2009) IMT Advanced (2013) |
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| 5G (2018) IMT-2020 (2021) |
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