PCM Encoding and Decoding:Aim:Intro

PCM Encoding and Decoding:
Aim:
Introduction to PCM encoding and decoding.
Introduction:
PCM Encoding:
The input to the PCM ENCODER module is an analog message. This must be constrained to a
defined bandwidth and amplitude range.
The maximum allowable message bandwidth will depend upon the sampling rate to be used. The
Nyquist criterion must be observed.
The amplitude range must be held within the ± 2.0 volts range of the TIMS ANALOG REFERENCE
LEVEL. This is in keeping with the input amplitude limits set for all analog modules.
A step-by-step description of the operation of the module follows:
1. the module is driven by an external TTL clock.
2. the input analog message is sampled periodically. The sample rate is determined by the
external clock.
3. the sampling is a sample-and-hold operation. It is internal to the module, and cannot be viewed
by the user . What is held is the amplitude of the analog message at the sampling instant.
4. each sample amplitude is compared with a finite set of amplitude levels. These are distributed
(uniformly, for linear sampling) within the range ± 2.0 volts (the TIMS ANALOG REFERENCE
LEVEL). These are the system quantizing levels.
5. each quantizing level is assigned a number, starting from zero for the lowest (most negative)
level, with the highest number being (L-1), where L is the available number of levels.
6. each sample is assigned a digital (binary) code word representing the number associated with
the quantizing level which is closest to the sample amplitude. The number of bits ‘n’ in the digital
code word will depend upon the number of quantizing levels. In fact, n = log2(L).
7. the code word is assembled into a time frame together with other bits as may be required
(described below). In the TIMS PCM ENCODER (and many commercial systems) a single extra
bit is added, in the least significant bit position. This is alternately a one or a zero. These bits are
used by subsequent
decoders for frame synchronization.
8. the frames are transmitted serially. They are transmitted at the same rate as the samples are
taken. The serial bit stream appears at the output of the module.
9. also available from the module is a synchronizing signal FS (‘frame synch’). This signals the
end of each data frame.
The PCM Ecoder Module:
Front panel layout of the PCM ENCODER
Note and understand the purpose of each of the input and output connections, and the threeposition
toggle switch. Counting from the top, these are:
• SLAVE: not used during this experiment. Do not connect anything to this input.
• MASTER: not used during this experiment. Do not connect anything to this output.
• SYNC. MESSAGE: periodic, ‘synchronized’, message. Either sinusoidal, or sinusoidallike
(‘sinuous’), its frequency being a sub-multiple of the MASTER CLOCK (being any
one of four frequencies selected by an on-board switch SW2). A message synchronized
to the system clock is convenient for obtaining stable oscilloscope displays. Having a
recognisable shape (but being more complex than a simple sine wave) gives a qualitative
idea of distortion during the decoding process (examined in a later experiment). See
Table A-1 in the Appendix to this experiment for more details.
• SELECT CODING SCHEME: a three-position toggle switch which selects the 4-bit or
7-bit encoding scheme of the analog samples; or (together with an onboard jumper
connection) the companding scheme.
• FS: frame synchronization, a signal which indicates the end of each data frame.
• Vin:: the analog signal to be encoded.
• PCM DATA: the output data stream, the examination of which forms the major part of
this experiment.
• CLK: this is a TTL (red) input, and serves as the MASTER CLOCK for the module.
Clock rate must be 10 kHz or less. For this experiment you will use the 8.333 kHz TTL
signal from the MASTER SIGNALS module.
The TIMS PCM time frame:
Each binary word is located in a time frame. The time frame contains eight slots of equal length,
and is eight clock periods long. The slots, from first to last, are numbered 7 through 0. These slots
contain the bits of a binary word. The least significant bit (LSB) is contained in slot 0. The LSB
consists of alternating ones and zeros. These are placed (‘embedded’) in the frame by the encoder
itself, and cannot be modified by the user. They are used by subsequent decoders to determine the
location of each frame in the data stream,
and its length. The remaining seven slots are available for the bits of the binary code word. Thus
the system is capable of a resolution of seven-bits maximum. This resolution, for purposes of
experiment, can be reduced to four bits (by front panel switch). The 4- bit mode uses only five of
the available eight slots - one for the embedded frame synchronization bits, and the remaining
four for the binary code word (in slots 4, 3, 2, and 1).
Experimental Procedure:
T1 select the TIMS companding A4-law with the on-board COMP jumper (in preparation
for a later part of the experiment).
T2 locate the on-board switch SW2. Put the LEFT HAND toggle DOWN and the RIGHT
HAND toggle UP. This sets the frequency of a message from the module at SYNC.
MESSAGE. This message is synchronized to a submultiple of the MASTER CLOCK
frequency.
Patching Up:
To determine some of the properties of the analog to digital conversion process it is best
to start with a DC message. This ensures completely stable oscilloscope displays, and
enables easy identification of the quantizing levels.
Selecting the 4-bit encoding scheme reduces the number of levels (24
) to be examined.
T3 insert the module into the TIMS frame. Switch the front panel toggle switch to 4-BIT
LINEAR (ie., no companding).
T4 patch the 8.333 kHz TTL SAMPLE CLOCK from the MASTER SIGNALS module to
the CLK input of the PCM ENCODER module.
T5 connect the Vin input socket to ground of the variable DC module.
T6 connect the frame synchronization signal FS to the oscilloscope ext. synch. input.
T7 on CH1-A display the frame synchronization signal FS. Adjust the sweep speed to
show three frame markers. These mark the end of each frame.
T8 on CH2-A display the CLK signal.
T9 record the number of clock periods per frame.
Currently the analog input signal is zero volts (Vin is grounded). Before checking with the oscilloscope,
consider what the PCM output signal might look like. Make a sketch of this signal, fully annotated. Then:
T10 on CH2-B display the PCM DATA from the PCM DATA output socket.
Except for the alternating pattern of ‘1’ and ‘0’ in the frame marker slot, you might have expected nothing
else in the frame (all zeros), because the input analog signal is at zero volts. But you do not now the coding
scheme.
There is an analog input signal to the encoder. It is of zero volts. This will have been coded into a 4-bit
binary output number, which will appear in each frame. It need not be ‘0000’. The same number appears in
each frame because the analog input is constant.
5 frames of 4-bit PCM output for zero amplitude input
Knowing:
1. the number of slots per frame is 8
2. the location of the least significant bit is coincident with the end of the frame
3. the binary word length is four bits
4. the first three slots are ‘empty’ (in fact filled with zeros, but these remain unchanged under all conditions
of the 4-bit coding scheme)
T11 identify the binary word in slots 4, 3, 2, and 1.
Quantizing levels for 4-bit linear encoding:
You will now proceed to determine the quantizing/encoding scheme for the 4-bit linear
case.
T12 remove the ground connection, and connect the output of the VARIABLE DC module
to Vin. Sweep the DC voltage slowly backwards and forwards over its complete range,
and note how the data pattern changes in discrete jumps.
T13 use the oscilloscope (CH1-B) to monitor the DC amplitude at Vin . Adjust Vin to its
maximum negative value. Record the DC voltage and the pattern of the 4-bit binary
number.
T14 slowly increase the amplitude of the DC input signal until there is a sudden change
to the PCM output signal format. Record the format of the new digital word, and the
input amplitude at which the change occurred.
T15 continue this process over the full range of the DC supply.
T16 draw a diagram showing the quantizing levels and their associated binary numbers.
4-bit data format
From measurements made so far you should be able to answer the questions:
• what is the sampling rate ?
• what is the frame width ?
• what is the width of a data bit ?
• what is the width of a data word ?
• how many quantizing levels are there ?
• are the quantizing levels uniformly (linearly) spaced ?
7-bit linear encoding
T17 change to 7-bit linear encoding by use of the front panel toggle switch.
T18 make sufficient measurements so that you can answer all of the above questions in
the section titled 4-bit data format above.
Companding:
This module is to be used in conjunction with the PCM DECODER in a later part of this
experiment. As a pair they have a companding option. There is compression in the
encoder, and expansion in the decoder. In the encoder this means the quantizing levels
are closer together for small input amplitudes - that is, in effect, that the input amplitude
peaks are compressed during encoding. At the decoder the ‘reverse action’ is introduced
to restore an approximate linear input/output characteristic.
It can be shown that this sort of characteristic offers certain advantages, especially when
the message has a high peak-to-average amplitude characteristic, as does speech, and
where the signal-to-noise ratio is not high.
T19 change to 4-bit companding by use of the front panel toggle switch.
T20 the TIMS A4 companding law has already been selected (first Task). Make
the necessary measurements to determine the nature of the law.
Periodic Messages:
T21 take a periodic message from the SYNC. MESSAGE socket.
T22 adjust the oscilloscope to display the message. Record its frequency and shape.
Check if these are compa