1. Digital Transmission Systems Part 1
Chapter 8
Digital Transmission Systems
Part 1
25/02/2013
Bahman R. Alyaei

2. 1 Basics of PCM
About 50% or less of the traffic carried on the PSTN is voice traffic which is initially analog.
These analog signals must be converted to a digital format compatible with the digital network.
The remaining of the PSTN traffic is digital data, a great portion of which is Internet-related that is already digital.
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3. Continue…
In Digital Networks, the transmission facilities and the switches are digital.
The digital waveform on the PSTN is based on Pulse Code Modulation (PCM).
In the design of PCM systems for PSTN, the error rate is maintained at BER = 1×10−3.
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4. Continue…
In PCM system, the incoming band limited voice signal (W = 4kHz) is
Sampled according to the Nyquist Rate fs = 2W = 8000 samples/sec,
Each sample is then quantized through Non-uniform Quantizer,
Then each quantized sample is encoded by a k = 8-bit ADC.
The bit rate Rb = kfs = 64 kbps.
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5. Continue…
Then, the transmission bandwidth for a single voice channel is approximately BT = 64 kHz.
The process of digitization
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6. “Mid-rise” or “Mid-tread”
2 Quantization
Logarithmic law
“Compression”
Linear Quantizer
“Mid-rise” or “Mid-tread”
Input signal
Non-linear quantizer
A Non-linear quantizer consists of a logarithmic law circuit called compressor followed by a linear quantizer.
On the receiver side, the inverse of the logarithmic law circuit is used, that is called expander.
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7. 2.1 Companding Companding stands for two words Compression Expansion.
Compression: takes place on the transmit side of the Transceiver Circuit, it reduces the dynamic range with little loss of fidelity
Expansion: takes place on the receive side of the Transceiver Circuit, and it returns the signal to its normal condition.
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8. Continue…
This is done by favoring low-level speech over higher-level speech.
Hence, more code segments are assigned to speech bursts at low level than at the higher levels, progressively more as level goes down.
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9. Continue…
A simple graphic representation of compression. Six-bit coding, eight six bit sequences per segment.
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10. Continue…
The figure in the previous slide explains the non-linear quantization process, where each sample is encoded with k = 6-bits.
The total number of levels L = 2k = 256.
Note that eight coded sequences are assigned to each level grouping.
The smallest range rises only V from the origin (0 V).
The largest range extends over 0.5 V, and it is assigned only eight coded sequences.
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11. Continue… There are two types of Non-linear Qunatizers:
A-law: European.
where x is the signal input amplitude and A = for E1 system
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12. A-law used for companding in Europe
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13. The 13-segment approximation of the A -law curve used with E1 PCM equipment
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14. Continue…
The figure in the previous slide shows the companding curve and resulting coding for the European E1 system.
Note that the curve consists of linear piecewise segments, seven above and seven below the origin.
The segment just above and the segment just below the origin each consists of two linear elements.
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15. Continue…
Counting the collinear elements by the origin, there are 16 segments.
Each segment has 16, 8-bit PCM codewords assigned.
These are the codewords that identify the voltage level of a sample at some moment in time.
The first bit (MSB) tells the distant-end receiver if that sample is a positive or a negative voltage.
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16. Continue…
Note that all the PCM words above the origin start with a binary 1, and those below the origin start with a binary 0.
The next three bits identify the segment.
There are 8 segments above the origin and 8 below (23 = 8).
The last 4 bits, shown in the figure as XXXX, identify where in the segment that voltage line is located.
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17. Continue…
Example: the code word is +ve and located in segment 4.
The European E1 system, coding of segment 4 (positive)
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18. Continue… µ-law: North American.
Where x is the signal input amplitude and µ = 255 for DS1 system (New).
µ = 100 for T1 system (Old).
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19. μ-Law used for companding in the United Sates.
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20. Piecewise linear approximation of the µ-law logarithmic curve
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21. Continue…
The figure in the previous slide shows an equivalent logarithmic curve for the North American DS1 system.
It uses a 15-segment approximation of the logarithmic µ -law curve (µ = 255).
The segments cutting the origin are collinear and are counted as one.
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22. Continue…
The first code element (MSB), indicates to the distant end whether the sample voltage is positive or negative.
The next three elements (bits) identify the segment.
The last four elements (bits) identify the actual quantum level inside the segment.
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23. Eight-level coding of the North American DS1 PCM system
Eight-level coding of the North American DS1 PCM system. Note that there are actually only 255 quantizing steps because steps 0 and 1 use the same bit sequence, thus avoiding a code sequence with no transitions (i.e., all 0s)
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24. 3 PCM Codec or TDM System
Codec is a contraction of the word group Coder–Decoder.
Codec: is a TDM transceiver.
Codec accepts multiple voice channels.
It digitizes (ADC) and multiplexes the information; and delivers a serial bit stream to the trunk line or link.
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25. Continue…
It receives voice signals from the telephone sets in the local network through the subscriber loop.
It also accepts a serial bit stream from the link, demultiplexes the digital information, and performs Digital-to-Analog Conversion (DAC).
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26. Simplified functional block diagram of a PCM codec or TDM system
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27. Continue…
The voice channel to be transmitted is passed through a 3.4-kHz LPF.
The output of the LPF is fed to a S/H Circuit to generate PAM signal.
The PAM signal (PAM highway) fed to a Channel Gate Circuit.
The release of the PAM highway samples is under the control of the Channel Gate which is controlled by a pulse derived from the transmit clock.
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28. Continue… The input to the Coder is the PAM highway.
It accepts a sample of each (n) channel gate in sequence and then generates the appropriate 8-bit signal character corresponding to each sample, which is the basic PCM signal.
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29. Continue…
The coder output (n PCM signals) is fed to the Digit Combiner where framing-alignment signals and necessary supervisory signaling digits corresponding to each channel are inserted in the appropriate time slots.
On the receive side, the Codec accepts the serial PCM bit stream through the Digit Separator.
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30. Continue…
At the Digit Separator, the n signals are regenerated and split, delivering the PCM signal to four locations to carry out the following processing functions:
Timing recovery,
Decoding,
Frame alignment,
Signaling (supervisory).
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31. Continue…
Timing Recovery keeps the receive clock in synchronism with the far-end transmit clock.
The receive clock provides the necessary gating pulses for the receive side of the PCM Codec.
The Frame-Alignment Circuit senses the presence of the frame-alignment signal at the correct time interval, thus providing the receive terminal with frame alignment.
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32. Continue…
The Decoder, under control of the receive clock, decodes the code character signals corresponding to each channel.
The output of the Decoder is the reconstituted pulses making up a PAM highway.
The Channel Gate accepts the PAM highway, gating the n-channel PAM highway in sequence under control of the receive clock.
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33. Continue…
The output of the Channel Gate is fed in turn to each channel filter, thus enabling the reconstituted analog voice signal to reach the appropriate voice path.
Gating pulses extract signaling information in the signaling processor and apply this information to each of the reconstituted voice channels with the supervisory signaling interface as required by the analog telephone system in question.
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34. Continue… There are two varieties of PCM Codec:
The North American, called DS1 or T1.
The European, called E1.
Both DS1 and E1 are TDM systems.
The frame duration of E1 and DS1 is Tf = 1/fs = 1/8000 = 125 μS.
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35. 4 E1 System
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36. Multiframe for E1 carrier
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37. Continue… E1 PCM system is a 32-channel system.
One frame = 32-channels.
Each channel consists of 8-bits.
We say that, each channel is allotted an 8-bit time slot (TS), TS0 through TS31.
Total No. of TS per frame = 32.
TS = Ts/Total no. of channels = 125μ/32 = μS.
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38. Continue…
The total no. of bits per E1 frame is Total no. of bits = 8×32 = 256 bits.
The E1 bit rate to the line is Rb = 256×8000 = Mbps.
Of the 32 channels (32 TS):
30 channels transmit speech (or data) derived from incoming telephone trunks
The remaining 2 channels transmit synchronization-alignment and signaling information.
25/02/2013
Bahman R. Alyaei

39. Continue…
E1 can be adapted for CCS, providing 31 data channels and employing a single synchronization channel,  and  the signaling protocol being transmitted on a different physical channel. (Today)
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40. Continue…
In TS0, a synchronizing code or word which is called Frame Alignment Word (FAW) is transmitted every second frame, occupying digits 2 through 8 as follows: *
This allows the receiver to lock onto the start of each frame and match up each channel in turn.
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Bahman R. Alyaei

41. Continue…
For the alignment mechanism to be maintained, the FAW does not need to be transmitted in every frame, only even frames.
In those frames (odd frames) without the synchronizing word called Frame Service Word (FSW), the second bit of TS0 is frozen at a 1 so that in these frames the synchronizing word cannot be imitated (mimicked).
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42. Continue…
It is therefore available for other functions, such as the transmission of the Alarms and Supervisory Signals.
An alarm must be sent to the transmitter when a device detects any of the following at the
Multiplexer
A power failure.
A failure of the codec.
Demultiplexer:
Loss of the signal.
Loss of frame alignment.
BER greater than 10−3.
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43. Continue…
The remaining bits in positions 4 to 8 (Spare bits) of TS0 (odd frames) can be used in a number of ways, such as
Transmission of supervisory information signals between exchanges.
In specific point-to-point applications
To establish a data link based on messages for operations management
Maintenance or monitoring of the transmission quality, and so on.
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44. Continue…
E1 allow for a full Cyclic Redundancy Check (CRC) to be performed across all bits transmitted in each frame, to detect if the circuit is losing bits (information), but this is not always used.
TS16 is used to carry the call-control signaling between the exchanges at either end of the PCM route.
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45. Continue… Framing and basic timing should be distinguished.
Framing: ensures that the PCM receiver is aligned regarding the beginning and end of a bit sequence or frame.
Timing: refers to the synchronization of the receiver clock, specifically, that it is in step with its companion far-end transmit clock.
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46. 4.1 Enhancements to E1
In order to enhance signaling information (dial pulses) for all 30 channels to be transmitted, the concept of Multiframe is introduced.
The Multiframe consists of 16 frames numbered 0-15.
A Multiframe is divided into two parts:
Sub-multiframe I (SMF-I): frames 0-7.
Sub-multiframe II (SMF-II): frames 8-15.
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47. Continue…
In Frame 0, TS16 contains the Multiframe Alignment Word (MFAW) and Multiframe Service Word (MFSW).
In Frames 1-15, TS16 contains signalling information for two channels.
The duration of each Multiframe is 2 mS (125 µS x 16).
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48. 5 Digital Signal 1 (DS1)
DS1 signal format
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49. Continue… DS1 PCM system is a 24-channel system.
One frame = 24-channels.
Each channel consists of 8-bits.
We say that, each channel is allotted an 8-bit time slot (TS), TS1 through TS24.
Total No. of TS per frame = 24.
TS = (8)(Ts/Total no. of bits per frame) = (8)(125μ/193) = μS.
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50. Continue…
The DS1 signal format, has one bit added as a framing bit called an “S” bit for synchronization.
The total no. of bits per DS1 frame is Total no. of bits = 8× = 193 bits.
The DS1 bit rate to the line is Rb = 193×8000 = Mbps.
In DS1, all the 24 channels are used to transmit speech (or data) derived from incoming telephone trunks.
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51. Frame structure of North American DS1 PCM system channel bank
If bits 1 to 6 and 8 are 0, then bit 7 is transmitted as binary 1
Frame structure of North American DS1 PCM system channel bank
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52. Continue…
Supervisory signaling is “in-band” where bit 8 of every sixth frame is “robbed” for supervisory signaling.
On each frame that has bit 8 “robbed” 7-bit coding is used versus 8-bit coding used on the other five frames.
Thus each equivalent voice channel carries its own signaling
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53. 5.1 Enhancement to DS1
A Superframe (Multiframe) consists of 12 consecutive frames.
Hence, we have developed 12 S-bits and they all are used for frame alignment/synchronization.
Thus, there is a 12-bit sequence, one S-bit frame from each frame.
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54. Continue… This 12-bit sequence is subdivided into two sequences:
The frame alignment pattern is and is located in the odd-numbered frames.
The Superframe-alignment pattern is and is located in the even-numbered frames.
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55. 25/02/2013
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56. Superframe for DS1
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57. 6 PCM Line Codes
For E1 trunks, the line coding is always HDB3 (High-Density Bipolar Order 3).
There are four rules for HDB3 coding:
More than three consecutive zeros are not allowed. For the fourth ‘0’ introduce a Violation bit.
Violation bit has to be of the same polarity as the previous mark ‘1’.
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58. Continue…
Two consecutive violation bits has to be of opposite polarity.
If the number of marks between two consecutive violation bits is even the format should be B00V where B is a stuffing bit and of opposite polarity to the previous mark. If the number of marks is an odd number the format should be 000V.
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59. Continue…
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60. Continue…
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61. Continue…
In DS1, Bipolar with Eight-Zero Substitution (B8ZS) line code is used.
In DS2, Bipolar with Six-Zero Substitution (B6ZS) line code is used.
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62. 7 Synchronization of Digital Signals
We can classify Higher-Order PCM Multiplexing Systems (Hierarchy) according to Data Signals Synchronization into three categories:
Synchronous.
Plesiochronous.
Asynchronous.
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63. 7.1 Synchronous
In a set of Synchronous signals, the digital transitions in the signals occur at exactly the same rate.
There may however be a phase difference due to network propagation time delay between the transitions of the two signals, and this would lie within specified limits.
In a synchronous network, all the clocks are traceable to one Primary Reference Clock (PRC).
The accuracy of the PRC is better than ±1 in 1011 and is derived from a cesium atomic standard.
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64. 7.2 Plesiochronous
If two digital signals are Plesiochronous, their transitions occur at “almost” the same rate, with any variation being constrained within tight limits.
For example, if two networks need to inter-work, their clocks may be derived from two different PRCs.
Although these clocks are extremely accurate, there’s a small frequency difference between one clock and the other.
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65. 7.3 Asynchronous
In the case of Asynchronous signals, the transitions of the signals don’t necessarily occur at the same nominal rate.
Asynchronous, in this case, means that the difference between two clocks is much greater than a Plesiochronous difference.
For example, if two clocks are derived from free-running quartz oscillators, they could be described as Asynchronous.
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66. 8 Higher Order PCM Multiplex Systems
Primary multiplex is typically E1 in Europe and DS1 in North America.
Higher-order PCM multiplex is developed out of several primary multiplex sources.
There are two PCM multiplexing systems:
Plesiochronous Digital Hierarchy (PDH).
SDH/SONET.
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67. 9 PDH In PDH, Stuffing or Justification bits are required.
Stuffing bits are extra frame alignment bits (word) introduced by the Higher-Order Multiplexer after buffering.
As a result, the output of the Higher-Order Multiplexer is slightly faster than the original rate of the multiplexed signal.
Therefore, bits at the output of PDH multiplexer buffer must be read at a rate slightly faster than the input.
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68. Continue…
Hence, each Higher-Order Multiplexer needs its own primary clock.
Therefore, this type of Higher-Order Multiplexing is called Plesiochronous Digital Hierarchy (PDH).
PDH is bit by bit multiplexing scheme (Bit Interleaving).
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69. Continue…
Bit Interleaving is simpler than Byte Interleaving because it is independent of frame structure and also requires less memory capacity.
There are two PDH systems:
European PDH system.
North American PDH system
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70. Continue…
Interleaving digital signals, a) Bit interleaving, b) Word interleaving (word length = 3 bits)
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71. European Plesiochronous Digital Hierarchy
9.1 European PDH System
E E E3 E4
European Plesiochronous Digital Hierarchy
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72. 9.2 North American PDH System
American Plesiochronous Digital Hierarchy
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73. 9.3 Disadvantages of PDH It is plesiochronous.
Not only E1 and DS1 are incompatible, the Higher-Order Multiplexers are also incompatible, specialized interface equipment is required to inter-work the two hierarchies.
To recover a 64 kbps channel from a 140 Mbps (E4) PDH signal, it’s necessary to demultiplex the signal all the way down to the 2 Mbps level (E1) before the location of the 64 kbps channel can be identified (add and drop), due to Bit Interleaving concept.
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74. 9.4 Digital Loop Carrier (DLC)
DLC Is a system which uses digital transmission to extend the range of the local loop farther than would be possible using only twisted pair copper wires.
DLC is one method of extending the metallic subscriber plant by using one or more E1 or DS1 configurations.
A DLC digitizes and multiplexes the individual signals carried by the local loops onto a single data stream on the DLC segment.
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75. Continue…
As an example, the Single Loop Carrier SLC-120 employs four E1 configurations to derive an equivalent 120 voice channels.
Another example, the SLC-96 employs four DS1 configurations to derive an equivalent 96 voice channels.
The digital transmission facility used by a DLC system may be repeated wire-pair cable, optical fibers, either or both combined with digital multiplexers, or other appropriate media.
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76. Continue…
Digital Loop Carrier Systems
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77. Digital Loop Carrier System and Terminal
Continue…
Digital Loop Carrier System and Terminal
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