The Portfolio object implements mean-variance portfolio optimization.
Every property and function of the Portfolio object is public, although
some properties and functions are hidden. See
the properties and functions of the Portfolio object. The Portfolio
object is a value object where every instance of the object is a distinct
version of the object. Since the Portfolio object is also a MATLAB® object,
it inherits the default functions associated with MATLAB objects.
The Portfolio object and its functions are an interface for mean-variance portfolio optimization. So, almost everything you do with the Portfolio object can be done using the associated functions. The basic workflow is:
Design your portfolio problem.
Portfolio to create the
Portfolio object or use the various "set" functions to set up your
Use estimate functions to solve your portfolio problem.
In addition, functions are available to help you view intermediate
results and to diagnose your computations. Since MATLAB features are part of a Portfolio object, you can save and load objects
from your workspace and create and manipulate arrays of objects. After settling on a
problem, which, in the case of mean-variance portfolio optimization, means that you
have either data or moments for asset returns and a collection of constraints on
your portfolios, use
Portfolio to set the properties for
the Portfolio object.
Portfolio lets you create an object
from scratch or update an existing object. Since the Portfolio object is a value
object, it is easy to create a basic object, then use functions to build upon the
basic object to create new versions of the basic object. This is useful to compare a
basic problem with alternatives derived from the basic problem. For details, see
Creating the Portfolio Object.
You can set properties of a Portfolio object using either
Portfolio or various "set" functions.
Although you can also set properties directly, it is not recommended since error-checking is not performed when you set a property directly.
Portfolio object supports setting
properties with name-value pair arguments such that each argument name is a property
and each value is the value to assign to that property. For example, to set the
AssetCovar properties in an
existing Portfolio object
p with the values
C, use the
p = Portfolio(p, 'AssetMean', m, 'AssetCovar', C);
In addition to
Portfolio, which lets you set
individual properties one at a time, groups of properties are set in a Portfolio
object with various “set” and “add” functions. For
example, to set up an average turnover constraint, use the
setTurnover function to specify the
bound on portfolio average turnover and the initial portfolio. To get individual
properties from a Portfolio object, obtain properties directly or use an assortment
of “get” functions that obtain groups of properties from a Portfolio
Portfolio object and the "set"
functions have several useful features:
Portfolio and the "set"
functions try to determine the dimensions of your problem with either
explicit or implicit inputs.
Portfolio and the "set"
functions try to resolve ambiguities with default choices.
Portfolio and the "set"
functions perform scalar expansion on arrays when possible.
The associated Portfolio object functions try to diagnose and warn about problems.
The Portfolio object uses the default display functions provided
by MATLAB, where
a Portfolio object and its properties with or without the object variable
Save and load Portfolio objects using the MATLAB
Estimating efficient portfolios and efficient frontiers is the primary purpose of the portfolio optimization tools. A collection of “estimate” and “plot” functions provide ways to explore the efficient frontier. The “estimate” functions obtain either efficient portfolios or risk and return proxies to form efficient frontiers. At the portfolio level, a collection of functions estimates efficient portfolios on the efficient frontier with functions to obtain efficient portfolios:
At the endpoints of the efficient frontier
That attain targeted values for return proxies
That attain targeted values for risk proxies
Along the entire efficient frontier
These functions also provide purchases and sales needed to shift from an initial or current portfolio to each efficient portfolio. At the efficient frontier level, a collection of functions plot the efficient frontier and estimate either risk or return proxies for efficient portfolios on the efficient frontier. You can use the resultant efficient portfolios or risk and return proxies in subsequent analyses.
Although all functions associated with a Portfolio object are designed to work on a scalar
Portfolio object, the array capabilities of MATLAB enable you to set up and work with arrays of Portfolio objects. The
easiest way to do this is with the
repmat function. For example, to
create a 3-by-2 array of Portfolio
p = repmat(Portfolio, 3, 2); disp(p)
p(i,j) = Portfolio(p(i,j), ... );
Portfoliofor the (
j) element of a matrix of Portfolio objects in the variable
If you set up an array of Portfolio objects, you can access
properties of a particular Portfolio object in the array by indexing
so that you can set the lower and upper bounds
element of a 3-D array of Portfolio objects with
p(i,j,k) = setBounds(p(i,j,k),lb, ub);
[lb, ub] = getBounds(p(i,j,k));
You can subclass the Portfolio object to override existing functions
or to add new properties or functions. To do so, create a derived
class from the
Portfolio class. This gives you
all the properties and functions of the
along with any new features that you choose to add to your subclassed
Portfolio class is derived from an
abstract class called
of this, you can also create a derived class from
implements an entirely different form of portfolio optimization using
properties and functions of the
The portfolio optimization tools follow these conventions regarding the representation of different quantities associated with portfolio optimization:
Asset returns or prices are in matrix form with samples for a given asset going down the rows and assets going across the columns. In the case of prices, the earliest dates must be at the top of the matrix, with increasing dates going down.
The mean and covariance of asset returns are stored in a vector and a matrix and the tools have no requirement that the mean must be either a column or row vector.
Portfolios are in vector or matrix form with weights for a given portfolio going down the rows and distinct portfolios going across the columns.
Constraints on portfolios are formed in such a way that a portfolio is a column vector.
Portfolio risks and returns are either scalars or column vectors (for multiple portfolio risks and returns).