A Series On The Birth of Signaling and The Evolution of Diameter in The Cload

History of Signaling

By: Lysandria G Serrano

Introduction

For those of us in the world of technology, specifically the telecommunications world, who are NOT engineers but may work in the supporting roles such as myself, may struggle with learning just what exactly is signaling and where does it originate?  I am currently completing my MBA in Organizational Development and am building my career in a great telecommunications company that specializes in a technology called Diameter.  So here is what I have learned with the help of a great textbook and the fantastic minds of our Products/Solutions Engineers for Diametriq.

Origination

If you who are looking for a better understanding of signaling within the world of Diameter, it may help to understand just where signaling originated. Upon researching, it was discovered that all routes of information on the history of Signaling came from the same source: Signaling System No. 7 (SS7): Protocol, Architecture, and Service, authored by Mr. Lee Dryburgh and Jeff Hewett.  Below are some excerpts from this book to help aide in understanding where Signaling originated.

To appreciate signaling in today's network and its role in future networks, let's examine the history of signaling. The history of signaling has been inextricably linked to the history of telecommunications and, in particular, switching. As telecommunications advances, so do the signaling systems that support it.

What is signaling? The International Telecommunications Union Telecommunication Standardization Sector (ITU-T) defines signaling as: "The exchange of information (other than by speech) specifically concerned with the establishment, release and other control of calls, and network management, in automatic telecommunications operation." SS7 was defined as an international standard by ITU-T in its 1980 (Yellow Book) Q.7XX-series recommendations.

In telecommunications, the network's components must indicate (that is, signal) certain information to each other to coordinate themselves for providing services. As such, the signaling network can be considered the telecommunications network's nervous system. It breathes life into the infrastructure. Richard Manterfield, author of Telecommunications Signaling, has stated this poetically:

"Without signaling, networks would be inert and passive aggregates of components. Signaling is the bond that provides dynamism and animation, transforming inert components into a living, cohesive and powerful medium."

1889-1976

The earliest telephone switches were manual; operators used a switchboard and wire cords to connect and disconnect all calls. The first manual exchange occurred in 1878 in New Haven, Connecticut. It was introduced to avoid the imminent problem of running wires from each telephone to every other telephone (a fully meshed topology). The first manual switch appeared in Great Britain in 1879. It was also within this same year that subscribers came to be called by numbers rather than by names. Within a decade of introducing the manual switch, the United States had 140,000 subscribers and a staggering 8000 exchanges—that is, a switch for every 17.5 subscribers!

A subscriber who was connected to a manual switch would crank a lever to electronically send an alerting signal that lit up a bulb on the operator's switchboard. The operator would then connect her telephone to the calling line, and ask for the called number. Next the operator would connect her telephone to the called line, where she would place a ringing signal. If the called party answered the call, the operator would establish the connection by plugging in a cord between the two terminal jacks on the switchboard.

Signaling, as we know it today, began around 1889 with the invention of the Strowger exchange (which was patented 1891). The Strowger exchange was an electromechanical device that provided automatic switching using the simple idea of two-motion selectors for establishing calls between two subscribers. It was also known as a step-by-step switch because it followed pre-wired switching stages from start to finish. Strowgers' dial telephone is considered the precursor of today's touch-tone phone. It had three buttons: one for hundreds, one for tens, and one for units. To call the number 322, the caller had to push the hundreds button three times, the tens button two times, and the units button two times. In 1896 the Automatic Electric Company developed a rotary dial to generate the pulses. This method of transmitting the dialed digits became known as pulse dialing and was commonplace until the latter half of the twentieth century, when tone dialing became available.

Even in Great Britain in 1930, the majority of all local and long distance calls were still connected manually through an operator. But gradually, calls placed between subscribers served by the same local switch could be dialed without the help of an operator. Therefore, only subscriber signaling was required because an operator would perform any inter-switch signaling manually. In the decades that followed, it became possible to dial calls between subscribers who were served by nearby switches. Thus the requirement for network signaling was born. Most large U.S. cities had automatic exchanges by 1940.

Direct Distance Dialing (DDD) was introduced in the United States in the 1950s. DDD allowed national long distance calls to be placed without operator assistance, meaning that any switch in the United States could route signaling to any other switch in the country. International Direct Distance Dialing (IDDD) became possible in the 1960s, thus creating the requirement for signaling between international switches.

1976 to Present Day

Another form of signaling was introduced in 1976: Common Channel Signaling (CCS). CCS has been used to implement applications beyond the scope of basic telephone service, including Intelligent Networks (INs), supplementary services, and signaling in cellular mobile networks. As you will learn, SS7 is the modern day CCS system that is used for network signaling. As with any technical subject, signaling can be split into a number of classifications. The broadest classification is whether the signaling is subscriber or networked signaling.

Network signaling takes place between nodes in the core network. This is generally from the local switch, through the core network, and to the destination local switch—in other words, between the calling and the called party switch.

For obvious reasons, the signaling system employed on the local loop (between the subscriber and the local switch) differs from that which is used in the core network. The subscriber must only generate a limited number of signals: on or off hook, called party digits, and possibly a few commands for supplementary services.

In comparison, a modern core network must perform very complex signaling, such as those to support database driven services like Local Number Portability (LNP), credit or calling card validation, and cellular roaming. Therefore, subscriber signaling systems are simple compared to modern network signaling systems.

Network signaling was previously implemented using Channel Associated Signaling (CAS) techniques and systems. However, for the past two decades, it has been replaced with Common Channel Signaling (CCS) systems. Signaling System No. 7 (SS7) is almost the exclusive CSS system; thus, CCS can almost be taken to refer exclusively to the use of SS7. SS7 is both network architecture and a series of protocols that provide telecommunications signaling.

SS7 to Diameter

When cellular/mobile networks were being built the SS7 technology was built into its architecture, the 2G mobile core. This architecture in the 2G mobile core uses SS7 to control signaling that controls communication from voice to data network elements then to the centralized database.

As 2G grew and evolved into 3G, the SS7 controlled the signaling communication between the voice networks and the centralized databases. What about data networks?  The SS7 was utilized in the 3G in conjunction with Diameter to control signaling to communicate from the data networks to the centralized databases.  This is the point to where Diameter is introduced in the signaling realm.

What is Diameter? In layman terms Diameter is the evolved product of SS7 and controls the signaling within networks of voice, data and multi-media services. In today's 4G/LTE world Diameter has now overtaken SS7 and controls the signaling communication from the data network to the centralized databases.  Diameter also does this same control of signaling from the voice networks to the data networks then to the centralized databases.

In closing it is truly amazing when you look back at how signaling has evolved trough time. Beginning with signals telling an operator to connect one line to another for people to communicate; to the simple light handed tough of a button or touch screen to relay a text, picture or voice to another. Behind the scenes, or shall we say "behind the network" there is an ongoing evolution in the mobile core world of how voice and data is controlled and sent to centralized databases that allows us to stay connected in our small networked worlds!

Resources

ITU-T Rec. Q.7 http://www.itu.int/rec/T-REC-Q.700/en

ITU-T Rec. Q.9 (11/88) Vocabulary of Switching and Signaling Terms.

Manterfield, R. Telecommunications Signaling. New York, New York; IEEE Publishing, 1999.

Dryburgh, L., Hewett, J.  Signaling System No. 7 (SS7/C7): Protocol, Architecture, and Services