# replaceBlock

Replace or update control design blocks in generalized LTI model

## Syntax

Mnew = replaceBlock(M,Block1,Value1,...,BlockN,ValueN)
Mnew = replaceBlock(M,blockvalues)
Mnew = replaceBlock(...,mode)

## Description

Mnew = replaceBlock(M,Block1,Value1,...,BlockN,ValueN) replaces the Control Design Blocks Block1,...,BlockN of M with the specified values Value1,...,ValueN. M is a Generalized LTI model or a Generalized matrix.

Mnew = replaceBlock(M,blockvalues) specifies the block names and replacement values as field names and values of the structure blockvalues.

Mnew = replaceBlock(...,mode) performs block replacement on an array of models M using the substitution mode specified by mode.

## Input Arguments

 M Generalized LTI model, Generalized matrix, or array of such models. Block1,...,BlockN Names of Control Design Blocks in M. The replaceBlock command replaces each listed block of M with the corresponding values Value1,...,ValueN that you supply. If a specified Block is not a block of M, replaceBlock that block and the corresponding value. Value1,...,ValueN Replacement values for the corresponding blocks Block1,...,BlockN. The replacement value for a block can be any value compatible with the size of the block, including a different Control Design Block, a numeric matrix, or an LTI model. If any value is [], the corresponding block is replaced by its nominal (current) value. blockvalues Structure specifying blocks of M to replace and the values with which to replace those blocks. The field names of blockvalues match names of Control Design Blocks of M. Use the field values to specify the replacement values for the corresponding blocks of M. The replacement values may be numeric values, Numeric LTI models, Control Design Blocks, or Generalized LTI models. mode Block replacement mode for an input array M of Generalized matrices or LTI models, specified as one of the following values: '-once' (default) — Vectorized block replacement across the model array M. Each block is replaced by a single value, but the value may change from model to model across the array. For vectorized block replacement, use a structure array for the input blockvalues, or cell arrays for the Value1,...,ValueN inputs. For example, if M is a 2-by-3 array of models:Mnew = replaceBlock(M,blockvalues,'-once'), where blockvalues is a 2-by-3 structure array, specifies one set of block values blockvalues(k) for each model M(:,:,k) in the array.Mnew = replaceBlock(M,Block,Value,'-once'), where Value is a 2-by-3 cell array, replaces Block by Value{k} in the model M(:,:,k) in the array.'-batch' — Batch block replacement. Each block is replaced by an array of values, and the same array of values is used for each model in M. The resulting array of model Mnew is of size [size(M) Asize], where Asize is the size of the replacement value. When the input M is a single model, '-once' and '-batch' return identical results. Default: '-once'

## Output Arguments

 Mnew Matrix or linear model or matrix where the specified blocks are replaced by the specified replacement values. Mnew is a numeric array or numeric LTI model when all the specified replacement values are numeric values or numeric LTI models.

## Examples

### Replace Control Design Block with Numeric Values

This example shows how to replace a tunable PID controller (tunablePID) in a Generalized LTI model by a pure gain, a numeric PI controller, or the current value of the tunable controller.

1. Create a Generalized LTI model of the following system:

where the plant $G\left(s\right)=\frac{\left(s-1\right)}{{\left(s+1\right)}^{3}}$, and C is a tunable PID controller.

G = zpk(1,[-1,-1,-1],1);
C = tunablePID('C','pid');
Try = feedback(G*C,1)
2. Replace C by a pure gain of 5.

T1 = replaceBlock(Try,'C',5);

T1 is a ss model that equals feedback(G*5,1).

3. Replace C by a PI controller with proportional gain of 5 and integral gain of 0.1.

C2 = pid(5,0.1);
T2 = replaceBlock(Try,'C',C2);

T2 is a ss model that equals feedback(G*C2,1).

4. Replace C by its current (nominal) value.

T3 = replaceBlock(Try,'C',[]);

T3 is a ss model where C has been replaced by getValue(C).

### Sample Tunable Model Over Grid of Values

Consider the second-order filter represented by:

$F\left(s\right)=\frac{{\omega }_{n}^{2}}{{s}^{2}+2\zeta {\omega }_{n}s+{\omega }_{n}^{2}}.$

Sample this filter at varying values of the damping constant $\zeta$ and the natural frequency ${\omega }_{n}$. Create a tunable model of the filter by using tunable elements for $\zeta$ and ${\omega }_{n}$.

wn = realp('wn',3);
zeta = realp('zeta',0.8);
F = tf(wn^2,[1 2*zeta*wn wn^2])
F =

Generalized continuous-time state-space model with 1 outputs, 1 inputs, 2 states, and the following blocks:
wn: Scalar parameter, 5 occurrences.
zeta: Scalar parameter, 1 occurrences.

Type "ss(F)" to see the current value, "get(F)" to see all properties, and "F.Blocks" to interact with the blocks.

Create a grid of sample values.

wnvals = [3;5];
zetavals = [0.6 0.8 1.0];
[wngrid,zetagrid] = ndgrid(wnvals,zetavals);
Fsample = replaceBlock(F,'wn',wngrid,'zeta',zetagrid);
size(Fsample)
2x3 array of state-space models.
Each model has 1 outputs, 1 inputs, and 2 states.

The ndgrid command produces a full 2-by-3 grid of parameter combinations. Thus, Fsample is a 2-by-3 array of state-space models. Each entry in the array is a state-space model that represents F evaluated at the corresponding (wn, zeta) pair. For example, Fsample(:,:,2,3) has wn = 5 and zeta = 1.0.

damp(Fsample(:,:,2,3))

Pole        Damping       Frequency      Time Constant

-5.00e+00     1.00e+00       5.00e+00         2.00e-01
-5.00e+00     1.00e+00       5.00e+00         2.00e-01

## Tips

• Use replaceBlock to perform parameter studies by sampling Generalized LTI models across a grid of parameters, or to evaluate tunable models for specific values of the tunable blocks. See Examples.

• For additional options for sampling control design blocks, including concurrent sampling, use sampleBlock.

• To take random samples of control design blocks, see rsampleBlock