Eigen库矩阵运算使用方法

Eigen库矩阵运算使用方法 Eigen库矩阵运算使用方法

Eigen这个类库，存的东西好多的，来看一下主要的几个头文件吧：

——Core

有关矩阵和数组的类，有基本的线性代数（包含 三角形 和 自伴乘积 相关），还有相应对数组的 *** 作。

——Geometry

几何学的类，有关转换、平移、进位制、2D旋转、3D旋转（四元组和角轴相关）

——LU

逻辑单元的类，有关求逆，求行列式，LU分解解算器（FullPivLU,PartialPivLU)

——Cholesky

包含LLT和LDLT的乔里斯基因式分解法。

（小科普：Cholesky分解是把一个对称正定的矩阵表示成一个下三角矩阵L和其转置的乘积的分解）

——Householder

豪斯霍尔德变换，这个模块供几个线性代数模块使用。

（Householder transform:  维基百科 ）

——SVD

奇异值分解，最小二乘解算器解决奇异值分解。

——QR

QR分解求解，三种方法：HouseholderQR、ColPivHouseholderQR、FullPivHouseholderQR

——Eigenvalues

特征值和特征向量分解的方法：EigenSolver、SelfAdjointEigenSolver、ComplexEigenSolver

——Sparse

稀疏矩阵相关类，对于稀疏矩阵的存储及相关基本线性代数

——Dense

包含： Core、Gelometry、LU、Cholesky、SVD、QR和Eigenvalues模块（头文件）

——Eigen

包含上述所有的模块（头文件）

矩阵定义

#include <Eigen/Dense>
#include <Eigen/Core>


//Static Matrix

Matrix<double, 3, 3> A;               // Fixed rows and cols. Same as Matrix3d.

Matrix<double, 3, 3, RowMajor> E;     // Row major; default is column-major.代表着行优先，在内存中，存储时按行存储

Matrix3f P, Q, R;                     // 3x3 float matrix.

// Dynamic Matrix
Matrix<double, 3, Dynamic> B;         // Fixed rows, dynamic cols.

Matrix<double, Dynamic, Dynamic> C;   // Full dynamic. Same as MatrixXd.

//vector

Vector3f x, y, z;                     // 3x1 float matrix.

RowVector3f a, b, c;                  // 1x3 float matrix.

VectorXd v;                           // Dynamic column vector of doubles

基本使用方法

// Basic usage

// Eigen          // Matlab           // comments

x.size()          // length(x)        // vector size

C.rows()          // size(C,1)        // number of rows

C.cols()          // size(C,2)        // number of columns

x(i)              // x(i+1)           // Matlab is 1-based

C(i,j)            // C(i+1,j+1)       //

A.resize(4, 4);   // Runtime error if assertions are on.

B.resize(4, 9);   // Runtime error if assertions are on.

A.resize(3, 3);   // Ok; size didn't change.

B.resize(3, 9);   // Ok; only dynamic cols changed.

A << 1, 2, 3,     // Initialize A. The elements can also be

     4, 5, 6,     // matrices, which are stacked along cols

     7, 8, 9;     // and then the rows are stacked.

B << A, A, A;     // B is three horizontally stacked A's.

A.fill(10);       // Fill A with all 10's.

特殊矩阵生成

// Eigen                            // Matlab

MatrixXd::Identity(rows,cols)       // eye(rows,cols)

C.setIdentity(rows,cols)            // C = eye(rows,cols)

MatrixXd::Zero(rows,cols)           // zeros(rows,cols)

C.setZero(rows,cols)                // C = ones(rows,cols)

MatrixXd::Ones(rows,cols)           // ones(rows,cols)

C.setOnes(rows,cols)                // C = ones(rows,cols)

MatrixXd::Random(rows,cols)         // rand(rows,cols)*2-1        // MatrixXd::Random returns uniform random numbers in (-1, 1).

C.setRandom(rows,cols)              // C = rand(rows,cols)*2-1

VectorXd::LinSpaced(size,low,high)   // linspace(low,high,size)'

v.setLinSpaced(size,low,high)        // v = linspace(low,high,size)'

矩阵块 *** 作

// Matrix slicing and blocks. All expressions listed here are read/write.

// Templated size versions are faster. Note that Matlab is 1-based (a size N

// vector is x(1)...x(N)).

// Eigen                           // Matlab

x.head(n)                          // x(1:n)

x.head<n>()                        // x(1:n)

x.tail(n)                          // x(end - n + 1: end)

x.tail<n>()                        // x(end - n + 1: end)

x.segment(i, n)                    // x(i+1 : i+n)

x.segment<n>(i)                    // x(i+1 : i+n)

P.block(i, j, rows, cols)          // P(i+1 : i+rows, j+1 : j+cols)

P.block<rows, cols>(i, j)          // P(i+1 : i+rows, j+1 : j+cols)

P.row(i)                           // P(i+1, :)

P.col(j)                           // P(:, j+1)

P.leftCols<cols>()                 // P(:, 1:cols)

P.leftCols(cols)                   // P(:, 1:cols)

P.middleCols<cols>(j)              // P(:, j+1:j+cols)

P.middleCols(j, cols)              // P(:, j+1:j+cols)

P.rightCols<cols>()                // P(:, end-cols+1:end)

P.rightCols(cols)                  // P(:, end-cols+1:end)

P.topRows<rows>()                  // P(1:rows, :)

P.topRows(rows)                    // P(1:rows, :)

P.middleRows<rows>(i)              // P(i+1:i+rows, :)

P.middleRows(i, rows)              // P(i+1:i+rows, :)

P.bottomRows<rows>()               // P(end-rows+1:end, :)

P.bottomRows(rows)                 // P(end-rows+1:end, :)

P.topLeftCorner(rows, cols)        // P(1:rows, 1:cols)

P.topRightCorner(rows, cols)       // P(1:rows, end-cols+1:end)

P.bottomLeftCorner(rows, cols)     // P(end-rows+1:end, 1:cols)

P.bottomRightCorner(rows, cols)    // P(end-rows+1:end, end-cols+1:end)

P.topLeftCorner<rows,cols>()       // P(1:rows, 1:cols)

P.topRightCorner<rows,cols>()      // P(1:rows, end-cols+1:end)

P.bottomLeftCorner<rows,cols>()    // P(end-rows+1:end, 1:cols)

P.bottomRightCorner<rows,cols>()   // P(end-rows+1:end, end-cols+1:end)

矩阵元素交换以及转置等

// Of particular note is Eigen's swap function which is highly optimized.

// Eigen                           // Matlab

R.row(i) = P.col(j);               // R(i, :) = P(:, i)

R.col(j1).swap(mat1.col(j2));      // R(:, [j1 j2]) = R(:, [j2, j1])

// Views, transpose, etc; all read-write except for .adjoint().

// Eigen                           // Matlab

R.adjoint()                        // R'

R.transpose()                      // R.' or conj(R')

R.diagonal()                       // diag(R)

x.asDiagonal()                     // diag(x)

R.transpose().colwise().reverse(); // rot90(R)

R.conjugate()                      // conj(R)

矩阵四则运算

// All the same as Matlab, but matlab doesn't have *= style operators.

// Matrix-vector.  Matrix-matrix.   Matrix-scalar.

y  = M*x;          R  = P*Q;        R  = P*s;

a  = b*M;          R  = P - Q;      R  = s*P;

a *= M;            R  = P + Q;      R  = P/s;

                   R *= Q;          R  = s*P;

                   R += Q;          R *= s;

                   R -= Q;          R /= s;

单个元素 *** 作

// Vectorized operations on each element independently

// Eigen                  // Matlab

R = P.cwiseProduct(Q);    // R = P .* Q

R = P.array() * s.array();// R = P .* s

R = P.cwiseQuotient(Q);   // R = P ./ Q

R = P.array() / Q.array();// R = P ./ Q

R = P.array() + s.array();// R = P + s

R = P.array() - s.array();// R = P - s

R.array() += s;           // R = R + s

R.array() -= s;           // R = R - s

R.array() < Q.array();    // R < Q

R.array() <= Q.array();   // R <= Q

R.cwiseInverse();         // 1 ./ P

R.array().inverse();      // 1 ./ P

R.array().sin()           // sin(P)

R.array().cos()           // cos(P)

R.array().pow(s)          // P .^ s

R.array().square()        // P .^ 2

R.array().cube()          // P .^ 3

R.cwiseSqrt()             // sqrt(P)

R.array().sqrt()          // sqrt(P)

R.array().exp()           // exp(P)

R.array().log()           // log(P)

R.cwiseMax(P)             // max(R, P)

R.array().max(P.array())  // max(R, P)

R.cwiseMin(P)             // min(R, P)

R.array().min(P.array())  // min(R, P)

R.cwiseAbs()              // abs(P)

R.array().abs()           // abs(P)

R.cwiseAbs2()             // abs(P.^2)

R.array().abs2()          // abs(P.^2)

(R.array() < s).select(P,Q);  // (R < s ? P : Q)

矩阵缩减

// Reductions.

int r, c;

// Eigen                  // Matlab

R.minCoeff()              // min(R(:))

R.maxCoeff()              // max(R(:))

s = R.minCoeff(&r, &c)    // [s, i] = min(R(:)); [r, c] = ind2sub(size(R), i);

s = R.maxCoeff(&r, &c)    // [s, i] = max(R(:)); [r, c] = ind2sub(size(R), i);

R.sum()                   // sum(R(:))

R.colwise().sum()         // sum(R)

R.rowwise().sum()         // sum(R, 2) or sum(R')'

R.prod()                  // prod(R(:))

R.colwise().prod()        // prod(R)

R.rowwise().prod()        // prod(R, 2) or prod(R')'

R.trace()                 // trace(R)

R.all()                   // all(R(:))

R.colwise().all()         // all(R)

R.rowwise().all()         // all(R, 2)

R.any()                   // any(R(:))

R.colwise().any()         // any(R)

R.rowwise().any()         // any(R, 2)

矩阵点乘、叉乘及归一化

// Dot products, norms, etc.

// Eigen                  // Matlab

x.norm()                  // norm(x).    Note that norm(R) doesn't work in Eigen.

x.squaredNorm()           // dot(x, x)   Note the equivalence is not true for complex

x.dot(y)                  // dot(x, y)

x.cross(y)                // cross(x, y) Requires #include <Eigen/Geometry>

矩阵类型转换

//// Type conversion

// Eigen                           // Matlab

A.cast<double>();                  // double(A)

A.cast<float>();                   // single(A)

A.cast<int>();                     // int32(A)

A.real();                          // real(A)

A.imag();                          // imag(A)

// if the original type equals destination type, no work is done

// Note that for most operations Eigen requires all operands to have the same type:

MatrixXf F = MatrixXf::Zero(3,3);

A += F;                // illegal in Eigen. In Matlab A = A+F is allowed

A += F.cast<double>(); // F converted to double and then added (generally, conversion happens on-the-fly)

内存映射创建矩阵

// Eigen can map existing memory into Eigen matrices.

float array[3];

Vector3f::Map(array).fill(10);            // create a temporary Map over array and sets entries to 10

int data[4] = {1, 2, 3, 4};

Matrix2i mat2x2(data);                    // copies data into mat2x2

Matrix2i::Map(data) = 2*mat2x2;           // overwrite elements of data with 2*mat2x2

MatrixXi::Map(data, 2, 2) += mat2x2;      // adds mat2x2 to elements of data (alternative syntax if size is not know at compile time)

解方程

// Solve Ax = b. Result stored in x. Matlab: x = A \ b.

x = A.ldlt().solve(b));  // A sym. p.s.d.    #include <Eigen/Cholesky>

x = A.llt() .solve(b));  // A sym. p.d.      #include <Eigen/Cholesky>

x = A.lu()  .solve(b));  // Stable and fast. #include <Eigen/LU>

x = A.qr()  .solve(b));  // No pivoting.     #include <Eigen/QR>

x = A.svd() .solve(b));  // Stable, slowest. #include <Eigen/SVD>

// .ldlt() -> .matrixL() and .matrixD()

// .llt()  -> .matrixL()

// .lu()   -> .matrixL() and .matrixU()

// .qr()   -> .matrixQ() and .matrixR()

// .svd()  -> .matrixU(), .singularValues(), and .matrixV()

特征值

// Eigenvalue problems

// Eigen                          // Matlab

A.eigenvalues();                  // eig(A);

EigenSolver<Matrix3d> eig(A);     // [vec val] = eig(A)

eig.eigenvalues();                // diag(val)

eig.eigenvectors();               // vec

// For self-adjoint matrices use SelfAdjointEigenSolver<>

下面是我实际遇到的补充一下：

求广义逆矩阵

//Eigen中并没有求广义逆的函数，这里用SVD实现，数据类型大家可以看需修改为doubel

using Eigen::Dynamic;

using Eigen::Matrix;

using Eigen::RowMajor;

typedef Matrix<float, Dynamic, Dynamic, RowMajor> MatXf;

MatXf pinv(MatXf x)

{

    JacobiSVD<MatXf> svd(x,ComputeFullU | ComputeFullV);

    float  pinvtoler=1.e-8; //tolerance

    MatXf singularValues_inv = svd.singularValues();

    for ( long i=0; i<x.cols(); ++i) {

        if ( singularValues_inv(i) > pinvtoler )

            singularValues_inv(i)=1.0/singularValues_inv(i);

        else singularValues_inv(i)=0;

    }

    return svd.matrixV()*singularValues_inv.asDiagonal()*svd.matrixU().transpose();

}