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Convolutionally encode binary data and modulate using QAM method

TCM, in Digital Baseband sublibrary of Modulation

The Rectangular QAM TCM Encoder block implements trellis-coded modulation (TCM) by convolutionally encoding the binary input signal and mapping the result to a QAM signal constellation.

The **M-ary number** parameter is the number
of points in the signal constellation, which also equals the number
of possible output symbols from the convolutional encoder. (That is,
log_{2}(**M-ary number**) is
equal to n for a rate k/n convolutional code.)

If the convolutional encoder described by the trellis structure
represents a rate *k*/*n* code,
then the Rectangular QAM TCM Encoder block's input must be a binary
column vector with a length of *L***k* for
some positive integer *L*.

The output from the Rectangular QAM TCM Encoder block is a complex
column vector of length *L*.

To define the convolutional encoder, use the **Trellis
structure** parameter. This parameter is a MATLAB structure
whose format is described in Trellis Description of a Convolutional Code in
the Communications System Toolbox documentation. You can use this
parameter field in two ways:

If you want to specify the encoder using its constraint length, generator polynomials, and possibly feedback connection polynomials, then use a

`poly2trellis`

command within the**Trellis structure**field. For example, to use an encoder with a constraint length of 7, code generator polynomials of 171 and 133 (in octal numbers), and a feedback connection of 171 (in octal), set the**Trellis structure**parameter to`poly2trellis(7,[171 133],171)`

If you have a variable in the MATLAB workspace that contains the trellis structure, then enter its name as the

**Trellis structure**parameter. This way is faster because it causes Simulink to spend less time updating the diagram at the beginning of each simulation, compared to the usage in the previous bulleted item.

The encoder registers begin in the all-zeros state. You can
configure the encoder so that it resets its registers to the all-zeros
state during the course of the simulation. To do this, set the ```
Operation
mode
```

to **Reset on nonzero input via port**.
The block then opens a second input port, labeled `Rst`

.
The signal at the `Rst`

port is a scalar signal.
When it is nonzero, the encoder resets before processing the data
at the first input port.

The trellis-coded modulation technique partitions the constellation
into subsets called cosets, so as to maximize the minimum distance
between pairs of points in each coset. This block internally forms
a valid partition based on the value you choose for the **M-ary
number** parameter.

The figures below show the labeled set-partitioned signal constellations
that the block uses when **M-ary number** is `16`

, `32`

,
and `64`

. For constellations of other sizes, see
Biglieri, E., D. Divsalar, P. J. McLane and M. K. Simon, *Introduction
to Trellis-Coded Modulation with Applications*, New York,
Macmillan, 1991.

Coding gains of 3 to 6 decibels, relative to the uncoded case
can be achieved in the presence of AWGN with multiphase trellis codes.
For more information, see Biglieri, E., D. Divsalar, P. J. McLane
and M. K. Simon, *Introduction to Trellis-Coded Modulation
with Applications*, New York, Macmillan, 1991.

**Trellis structure**MATLAB structure that contains the trellis description of the convolutional encoder.

**Operation mode**In

`Continuous`

mode (default setting), the block retains the encoder states at the end of each frame, for use with the next frame.In

`Truncated (reset every frame)`

mode, the block treats each frame independently. I.e., the encoder states are reset to all-zeros state at the start of each frame.In

`Terminate trellis by appending bits`

mode, the block treats each frame independently. For each input frame, extra bits are used to set the encoder states to all-zeros state at the end of the frame. The output length is given by $$y=n\cdot (x+s)/k$$, where*x*is the number of input bits, and $$s=\text{constraintlength}-1$$ (or, in the case of multiple constraint lengths,*s*=`sum(ConstraintLength(i)-1)`

). The block supports this mode for column vector input signals.In

`Reset on nonzero input via port`

mode, the block has an additional input port, labeled`Rst`

. When the`Rst`

input is nonzero, the encoder resets to the all-zeros state.**M-ary number**The number of points in the signal constellation.

**Output data type**The output type of the block can be specified as a

`single`

or`double`

. By default, the block sets this to`double`

.

[1] Biglieri, E., D. Divsalar, P. J. McLane
and M. K. Simon, *Introduction to Trellis-Coded Modulation
with Applications*, New York, Macmillan, 1991.

[2] Proakis, John G., Digital Communications, Fourth edition, New York, McGraw-Hill, 2001

[3] Ungerboeck, G., "Channel Coding
with Multilevel/Phase Signals", *IEEE Trans. on Information
Theory*, Vol IT28, Jan. 1982, pp. 55–67.

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