Telecommunications JBCardenas © 1982 JBC © 1982~2006 v 3.01 HW1 due before Q3 © jbc Max group size 4, with XX is remainder modulo 6 of sum of equivalent.

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Presentation transcript:

Telecommunications JBCardenas © 1982 JBC © 1982~2006 v 3.01 HW1 due before Q3 © jbc Max group size 4, with XX is remainder modulo 6 of sum of equivalent number of 1 st letter of members’ surnames. Ex: Dense and Easy = 3. Package as a mini-thesis or mini-design. Problem: Determine the smallest number of transceivers system-wide, to provide mobile service while meeting the requirements stated below. Source: JBC 43-HW10THE Xx = (2 digits remainder mod 6 of sum of equivalent number of 1 st letters of members surnames)/100

Telecommunications JBCardenas © 1982 JBC © 1982~2006 v 3.01 HW2 Due before Q4 © jbc Switch Problem, 3 max per group, submit anytime before Q4 Jose B. Cardenas, C.P.M. EE, ECE HOMEWORK1 Given: Suppose a unidirectional or non-folded symmetrical 3 stages grid-coordinate switching matrix or network is used to provide full availability to 25 + X telephone subscribers. Find: Design or draw the 3-stages network with the minimum number of crosspoints. Use one page only letter size paper. Fill up the table below. Fill up the following table, and draw the switching network schematic for each option # of switches Size of each Switch# of Crosspoints Stage 1______ x ________ Stage 2______ x ________ Stage 3______ x ________ Total ____ This equivalent full crossbar has 900 crosspoints X is computed remainder modulo 11 of equivalent decimal number of sum of 1 st letters of your surnames, example letter P results to 30 subscribers. 30 inlets 30 outlets

Telecommunications JBCardenas © 1982 JBC © 1982~2006 v 3.01 HW3 due before Q4 © jbc Given the 6 stations network on the right and E1 total requirements between stations, below: SDH Capacity, maximum group size D E F B A C Link 4 is a ring. One fiber per section source: JBC 10-T040621B Find: 1.The smallest STM rate per link or ring. 2.The number of E1 terminations per station. Jose B. Cardenas, C.P.M. EE, ECE 10 E1s STM-4 30 E1s ADM Note:Number of E1 trunks for link A-F is integer average of equivalent number of 1 st letters of your surname names, e.g.: for C, results to an E1 requirement of 03. Example: A and B = 30 E1s.

Telecommunications JBCardenas © 1982 JBC © 1982~2006 v 3.01 HW4 due before Finals © jbc A B C D E Given: Link A-B serves as final route for 1 st order high usage routes A-E, A-D and A- C. The offered random erlang traffic and link capacities in VF 4Khz analog lines are as follows: 1 st order high usage routes AC, AD and AE overflow to AB Capacity Dimensioning Problem, individual submission S AE = 20 trunks A C = 14 erlangs Jose B. Cardenas, C.P.M. EE, ECE Find: 1.Compute total mean traffic A B for link A-B 2.Dimension the link A-B for carried traffic, or compute S AB 3.Compute mean traffic B C of route B-C 4.Dimension the trunks B-C for carried traffic or compute S BC The allowed blocking rate in both routes A-B and B-C is not to exceed 1%. S BC ABAB source: JBC THE BCBC PROVIDE A SOLUTION OUTLINE! Note: Trunks from A to D is equivalent sum of numbers of equivalent digits of 1 st letters of your surname and first name, e.g.: for J & C, VF trunks = 13.