Supported Operations for Optimization Variables and Expressions
Notation for Supported Operations
Optimization variables and expressions are the basic elements of the Problem-Based Optimization Workflow. For the legal operations on optimization variables and expressions:
x
andy
represent optimization arrays of arbitrary size (usually the same size).x2D
andy2D
represent 2-D optimization arrays.a
is a scalar numeric constant.M
is a constant numeric matrix.c
is a numeric array of the same size asx
.
Warning
The problem-based approach does not support complex values in an objective function, nonlinear equalities, or nonlinear inequalities. If a function calculation has a complex value, even as an intermediate value, the final result might be incorrect.
Operations Returning Optimization Expressions
These operations on optimization variables or expressions return an optimization expression.
Category | Operation | Example |
---|---|---|
Arithmetic | Add constant | x+c or c+x |
Add variable | x+y | |
Unary plus | +x | |
Subtract a constant | x-c | |
Subtract variables | x–y | |
Unary minus | -x | |
Multiply by a constant scalar | a*x or a.*x or
x*a or x.*a | |
Divide by a constant scalar | x/a or x./a or
a\x or a.\x | |
Pointwise multiply by an array | c.*x or x.*c | |
Pointwise divide by an array | x./c or c.\x | |
Pointwise multiply variables | x.*y | |
Matrix multiply variables | x2D*y2D , or x*y when
x or y is scalar | |
Matrix multiply variable and matrix | M*x2D or x2D*M | |
Dot product of variable and array | dot(x,c) or
dot(c,x) | |
Linear combination of variables | sum(x) , sum(x,dim) where
dim can be a scalar or vector,
sum(x,'all') , mean(x) ,
mean(x,dim) where dim can
be a scalar or vector, and mean(x,'all') | |
Product of array elements | prod(x) , prod(x,dim) , and
prod(x,'all') | |
Trace of matrix | trace(x2D) | |
Cumulative sum or product | cumsum(x) or cumprod(x) ,
including the syntaxes cumsum(x,dim) ,
cumsum(_,direction) ,
cumprod(x,dim) , and
cumprod(_,direction) | |
Differences | diff(x) , including the syntaxes
diff(x,n) and
diff(x,n,dim) | |
Concatenate and Reshape | Transpose | x' or x.' |
Concatenate | cat , vertcat , and
horzcat | |
Reshape | reshape(x,[10 1]) | |
Create diagonal matrix or get diagonal elements of matrix | diag(x2D) , where x2D is a
matrix or vector, including the syntax
diag(x2D,k) | |
Elementary Functions | Power of square matrix | x2D^a |
Pointwise power | x.^a | |
Square root | sqrt (x ) | |
Norm (Euclidean) |
fcn2optimexpr(@norm,x,Analysis="off") | |
Sine | sin (x ) | |
Cosine | cos (x ) | |
Secant | sec (x ) | |
Cosecant | csc (x ) | |
Tangent | tan (x ) | |
Arcsine | asin (x ) | |
Arccosine | acos (x ) | |
Arcsecant | asec (x ) | |
Arccosecant | acsc (x ) | |
Arctangent | atan (x ) | |
Exponential | exp (x ) | |
Logarithm | log (x ) | |
Hyperbolic sine | sinh (x ) | |
Hyperbolic cosine | cosh (x ) | |
Hyperbolic secant | sech (x ) | |
Hyperbolic cosecant | csch (x ) | |
Hyperbolic tangent | tanh (x ) | |
Inverse hyperbolic sine | asinh (x ) | |
Inverse hyperbolic cosine | acosh (x ) | |
Inverse hyperbolic secant | asech (x ) | |
Inverse hyperbolic cosecant | acsch (x ) | |
Inverse hyperbolic tangent | atanh (x ) |
Note
a^x
is not supported for an optimization variable
x
.
However, if you bound a
to be strictly positive, you can
use the equivalent exp(x*log(a))
.
Operations Returning Optimization Variables
These operations on optimization variables return an optimization variable.
Operation | Example |
---|---|
N-D numeric indexing (includes colon and
end ) | x(3,5:end) |
N-D logical indexing | x(ind) , where ind is a
logical array |
N-D string indexing | x(str1,str2) , where str1
and str2 are strings |
N-D mixed indexing (combination of numeric, logical, colon, end, and string) | x(ind,str1,:) |
Linear numeric indexing (includes colon and
end ) | x(17:end) |
Linear logical indexing | x(ind) |
Linear string indexing | x(str1) |
Operations on Optimization Expressions
Optimization expressions support all the operations that optimization variables
support, and return optimization expressions. Also, you can index into or assign
into an optimization expression using numeric, logical, string, or linear indexing,
including the colon and end
operators for numeric or linear
indexing.
Operations Returning Constraint Expressions
Constraints are any two comparable expressions that include
one of these comparison operators: ==
, <=
,
or >=
. Comparable expressions have the same size, or one of the
expressions must be scalar, meaning of size 1-by-1. For examples, see Expressions for Constraints and Equations.
Some Undocumented Operations Work on Optimization Variables and Expressions
Internally, some functions and operations call only the documented supported
operations. In these cases you can obtain sensible results from the functions or
operations. For example, currently squeeze
internally calls
reshape
, which is a documented supported operation. So if you
squeeze
an optimization variable then you can obtain a
sensible expression.
Unsupported Functions and Operations Require fcn2optimexpr
If your objective function or nonlinear constraint functions are not supported,
convert a MATLAB® function to an optimization expression by using fcn2optimexpr
. For examples, see Convert Nonlinear Function to Optimization Expression or the
fcn2optimexpr
function reference page.
See Also
OptimizationExpression
| OptimizationVariable
| fcn2optimexpr