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abs2active

Convert constraints from absolute to active format

Description

ActiveConSet = abs2active(AbsConSet,Index) transforms a constraint matrix to an equivalent matrix expressed in active weight format (relative to the index).

example

Examples

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Set up constraints for a portfolio optimization for portfolio w0 with constraints in the form A*w <= b, where w is absolute portfolio weights. (Absolute weights do not depend on the tracking portfolio.) Use abs2active to convert constraints in terms of absolute weights into constraints in terms of active portfolio weights, defined relative to the tracking portfolio w0. Assume three assets with the following mean and covariance of asset returns:

m = [ 0.14; 0.10; 0.05 ];
C = [ 0.29^2 0.4*0.29*0.17 0.1*0.29*0.08; 0.4*0.29*0.17 0.17^2 0.3*0.17*0.08;...
0.1*0.29*0.08 0.3*0.17*0.08 0.08^2 ];

Absolute portfolio constraints are the typical ones (weights sum to 1 and fall from 0 through 1), create the A and b matrices using portcons.

AbsCons = portcons('PortValue',1,3,'AssetLims', [0; 0; 0], [1; 1; 1;]);

Use the Portfolio object to determine the efficient frontier.

p = Portfolio('AssetMean', m, 'AssetCovar', C);
p = p.setInequality(AbsCons(:,1:end-1), AbsCons(:,end));
p.plotFrontier;

Figure contains an axes object. The axes object with title Efficient Frontier, xlabel Standard Deviation of Portfolio Returns, ylabel Mean of Portfolio Returns contains an object of type line. This object represents Efficient Frontier.

The tracking portfolio w0 is:

w0 = [ 0.1; 0.55; 0.35 ];

Use abs2active to compute the constraints for active portfolio weights.

ActCons = abs2active(AbsCons, w0)
ActCons = 8×4

    1.0000    1.0000    1.0000         0
   -1.0000   -1.0000   -1.0000         0
    1.0000         0         0    0.9000
         0    1.0000         0    0.4500
         0         0    1.0000    0.6500
   -1.0000         0         0    0.1000
         0   -1.0000         0    0.5500
         0         0   -1.0000    0.3500

Use the Portfolio object p and its efficient frontier to demonstrate expected returns and risk relative to the tracking portfolio w0.

p = p.setInequality(ActCons(:,1:end-1), ActCons(:,end));
p.plotFrontier;

Figure contains an axes object. The axes object with title Efficient Frontier, xlabel Standard Deviation of Portfolio Returns, ylabel Mean of Portfolio Returns contains an object of type line. This object represents Efficient Frontier.

Note, when using abs2active to compute “active constraints” for use with a Portfolio object, don't use the Portfolio object’s default constraints because the relative weights can be positive or negative (the setDefaultConstraints function for a Portfolio object specifies weights to be nonnegative).

Input Arguments

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Portfolio linear inequality constraint matrix expressed in absolute weight format, specified as [A b] such that A*w <= b, where A is a number of constraints (NCONSTRAINTS) by number of assets (NASSETS) weight coefficient matrix, and b and w are column vectors of length NASSETS. The value w represents a vector of absolute asset weights whose elements sum to the total portfolio value. See the output ConSet from portcons for additional details about constraint matrices.

Data Types: double

Index portfolio weights, specified as a NASSETS-by-1 vector. The sum of the index weights must equal the total portfolio value (for example, a standard portfolio optimization imposes a sum-to-1 budget constraint).

Data Types: double

Output Arguments

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Transformed portfolio linear inequality constraint matrix expressed in active weight format, returned in the form [A b] such that A*w <= b. The value w represents a vector of active asset weights (relative to the index portfolio) whose elements sum to zero.

Algorithms

abs2active transforms a constraint matrix to an equivalent matrix expressed in active weight format (relative to the index). The transformation equation is

Awabsolute=A(wactive+windex)babsolute.

Therefore

AwactivebabsoluteAwindex=bactive.

The initial constraint matrix consists of NCONSTRAINTS portfolio linear inequality constraints expressed in absolute weight format. The index portfolio vector contains NASSETS assets.

Version History

Introduced before R2006a