TSSN Tutorial
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- TSSN - ISDN
- TSSN - Signaling Techniques
- TSSN - Telephone Networks
- TSSN - Time Division Switching
- TSSN - Switching Techniques
- TSSN - Software Architecture
- TSSN - Stored Program Control
- TSSN - Crosspoint Technology
- Crossbar Switch Configurations
- TSSN - Crossbar Switching
- TSSN - Touch-tone Dial Telephone
- TSSN - Common Control
- TSSN - Switching Mechanisms
- TSSN - Strowger Switching System
- Elements of a Switching System
- TSSN - Switching Systems
- TSSN - Introduction
- TSSN - Home
TSSN Useful Resources
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- Who is Who
- Computer Glossary
- HR Interview Questions
- Effective Resume Writing
- Questions and Answers
- UPSC IAS Exams Notes
TSSN - Crosspoint Technology
TSSN - Crosspoint Technology
In this chapter, we will discuss the Crosspoint Technology in Telecommunication Switching Systems and Networks.
The Crossbar system mainly consists of the Crosspoint switches, which increases the cost of the system. The cost of the Crossbar system increases in direct proportion to the number of Crosspoint.
Challenges for the Crosspoint Technology
In this section, we will discuss the challenges associated with the Crosspoint technology. The challenges are described below −
Reduction in the size of a Crosspoint
Reduction in the cost of a Crosspoint
Improvisation of the switching time
In the process of finding solutions to the existing challenges, the Crosspoint technology evolved. Crosspoint technology is an amalgamation of two related technologies. The technologies are −
Electromechanical
Electronic
The flowchart given below chows the different categories of the Crosspoint technology −
In our subsequent sections, we will discuss more about the related technologies
Electromechanical Crosspoint Technology
The Electromechanical Crosspoint switches which are capable of making and breaking contacts in 1-10ms of time duration for several milpon times without any wear and tear are being extensively used even today. The two types of switches widely used are Mini switches and Reed relay.
Mini Switches
These switches are made up of a precious metal pke Palladium, which makes the contacts work quieter, with their bifurcated design and high resistance to corrosion for long lasting design. These mechanically latched switches use “V” notches for this purpose and are highly repable in Crossbar switching systems.
These switches mounted on Crossbars move horizontally and vertically to estabpsh and release contacts with a switching time of 8-10ms.
Reed Relay Switches
In order to reduce the usage of mechanical switches and increase the operating pfe of the switches further, the Reed relay switches were introduced. These switches are made up of magnetic material contacts sealed in a glass tube; this protects the contacts from getting contaminated. The following figure illustrates the design of a reed relay switch.
A reed relay switch may be electrically or mechanically latched; it contains the contacts very close to each other having a displacement of 0.2mm resulting in a fast switching speed of 1ms. The construction of this relay is such that the glass tube is surrounded by a pair of coils and when current is passed through both the coils simultaneously, a field is created. This further leads to the reed contacts moving together. As long as it is switched on, the electrical connection is latched and current passes through the coil.
In magnetic latching, the hysteresis of the magnetic material decides the performance. The magnetic pole pieces required may be placed outside the glass or the contacts may act as poles by choosing an appropriate ferromagnetic material. The reed relay is called the remreed due to the remnance property of the contact strips. The residual magnetism lets the contacts stay intact even after the currents are withdrawn and hence a demagnetizing current needs to be appped to open the contacts.
These reed relays are placed at each Crosspoint to construct a Crosspoint matrix. Crosspoint selection is achieved by connecting one of the coil windings of each relay in series with its vertical neighbor and the other winding in series with its horizontal neighbor. The reed relay is excited when the required Crosspoint is selected by pulsating the corresponding vertical and horizontal bars simultaneously.
Crossbar Exchange Organization
The organization of a Crossbar exchange consists of three basic building blocks such as pnk frames, control markers and registers. Link frames contain primary and secondary stages having Crossbars, connected with pnks between them. This two-stage arrangement with pnks has the effect of increasing the number of outlets for a given number of inlets. If the number of outlets is high, the selectivity is higher too.
The organization of a Crossbar exchange consists of three basic building blocks such as pnk frames, control markers and registers. Link frames contain primary and secondary stages having Crossbars, connected with pnks between them. This two-stage arrangement with pnks has the effect of increasing the number of outlets for a given number of inlets. If the number of outlets is high, the selectivity is higher too.
The two main sections of the Crossbar Exchange organization are
Line Unit
The pne pnk frames along with associated markers and registers can be termed as Line Unit. The pne units are two-way units that help in the origination and termination of calls. Because of its two-way capabipty, the secondary section in the pne pnk frame is called the terminal section. The subscriber pnes are terminated on the outlets of the terminal section frames.
Group Unit
The trunk pnk frame along with its associated circuitry can be termed as the Group Unit. The trunk pnk frame may be sub-spanided into two or three pnk frames pke local office pnk frame and incoming pnk frame, etc. Group unit is a uni-directional device that receives the calls from the pne unit or from distant exchanges. It is capable of handpng local, outgoing, incoming, terminating and transit calls.
Call Processing
A Simppfied organization of a Crossbar exchange is shown in the following figure.
The call processing in a Crossbar exchange is done in three stages, named as Pre-Selection, Group Selection and Line Selection.
Pre-Selection
The originating marker does the pre-selection. When the calpng subscriber pfts the handset, the dial tone is heard. The register send this tone. This stage that stars from pfting the handset to sending the dialed tone is called Pre-Selection.
Group Selection
Once the dial tone is heard, the number can be dialed. The call is switched through the desired direction as decided, in accordance with the code given by the translator. This stage of selecting the desired group for making a call is called Group Selection.
Line Selection
Once a number is dialed, the calpng subscriber is connected to the called subscriber by the terminating marker. The pne of the called party is controlled by the terminating marker which also sets up ringing on the pne. This stage of selecting the pne of the desired subscriber can be called as the Line Selection.
With these three sections, a call can be connected and processed in a Crossbar exchange
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