矩阵求导计算法则

转自:http://blog.sina.com.cn/s/blog_4a033b090100pwjq.html

求导公式(撇号为转置):

Y = A * X --> DY/DX = A'
Y = X * A --> DY/DX = A
Y = A' * X * B --> DY/DX = A * B'
Y = A' * X' * B --> DY/DX = B * A'

矩阵求导计算法则 <wbr>例题乘积的导数

d(f*g)/dx=(df'/dx)g+(dg/dx)f'

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于是把以前学过的矩阵求导部分整理一下:

1. 矩阵Y对标量x求导:

相当于每个元素求导数后转置一下,注意M×N矩阵求导后变成N×M了

Y = [y(ij)]--> dY/dx = [dy(ji)/dx]

 

2. 标量y对列向量X求导:

注意与上面不同,这次括号内是求偏导,不转置,对N×1向量求导后还是N×1向量

y = f(x1,x2,..,xn) --> dy/dX= (Dy/Dx1,Dy/Dx2,..,Dy/Dxn)'

 

3. 行向量Y'对列向量X求导:

注意1×M向量对N×1向量求导后是N×M矩阵。

将Y的每一列对X求偏导,将各列构成一个矩阵。

重要结论:

dX'/dX =I

d(AX)'/dX =A'

 

4. 列向量Y对行向量X’求导:

转化为行向量Y’对列向量X的导数,然后转置。

注意M×1向量对1×N向量求导结果为M×N矩阵。

dY/dX' =(dY'/dX)'

 

5. 向量积对列向量X求导运算法则:

注意与标量求导有点不同。

d(UV')/dX =(dU/dX)V' + U(dV'/dX)

d(U'V)/dX =(dU'/dX)V + (dV'/dX)U'

重要结论:

d(X'A)/dX =(dX'/dX)A + (dA/dX)X' = IA + 0X' = A

d(AX)/dX' =(d(X'A')/dX)' = (A')' = A

d(X'AX)/dX =(dX'/dX)AX + (d(AX)'/dX)X = AX + A'X

 

6. 矩阵Y对列向量X求导:

将Y对X的每一个分量求偏导,构成一个超向量。

注意该向量的每一个元素都是一个矩阵。

 

7. 矩阵积对列向量求导法则:

d(uV)/dX =(du/dX)V + u(dV/dX)

d(UV)/dX =(dU/dX)V + U(dV/dX)

重要结论:

d(X'A)/dX =(dX'/dX)A + X'(dA/dX) = IA + X'0 = A

 

8. 标量y对矩阵X的导数:

类似标量y对列向量X的导数,

把y对每个X的元素求偏导,不用转置。

dy/dX = [Dy/Dx(ij) ]

重要结论:

y = U'XV= ΣΣu(i)x(ij)v(j) 于是 dy/dX = [u(i)v(j)] =UV'

y = U'X'XU 则dy/dX = 2XUU'

y =(XU-V)'(XU-V) 则 dy/dX = d(U'X'XU - 2V'XU + V'V)/dX = 2XUU' - 2VU' +0 = 2(XU-V)U'

 

9. 矩阵Y对矩阵X的导数:

将Y的每个元素对X求导,然后排在一起形成超级矩阵。

 

10.乘积的导数

d(f*g)/dx=(df'/dx)g+(dg/dx)f'

结论

d(x'Ax)=(d(x'')/dx)Ax+(d(Ax)/dx)(x'')=Ax+A'x (注意:''是表示两次转置)

 

 

 

 

Notation

  • d/dx (y) is a vector whose (i) element is dy(i)/dx
  • d/dx (y) is a vector whose (i) element is dy/dx(i)
  • d/dx (yT) is a matrix whose (i,j) element is dy(j)/dx(i)
  • d/dx (Y) is a matrix whose (i,j) element is dy(i,j)/dx
  • d/dX (y) is a matrix whose (i,j) element is dy/dx(i,j)

 

Note that the Hermitian transpose is not used because complex conjugates are not analytic.

In the expressions below matrices and vectors ABC do not depend on X.

Derivatives of Linear Products

  • d/dx (AYB) =A * d/dx (Y) * B
    • d/dx (Ay) =A * d/dx (y)
  • d/dx (xTA) =A
    • d/dx (xT) =I
    • d/dx (xTa) = d/dx (aTx) = a
  • d/dX (aTXb) = abT
    • d/dX (aTXa) = d/dX (aTXTa) = aaT
  • d/dX (aTXTb) = baT
  • d/dx (YZ) =Y * d/dx (Z) + d/dx (Y) * Z

Derivatives of Quadratic Products

  • d/dx (Ax+b)TC(Dx+e) = ATC(Dx+e) + DTCT(Ax+b)
    • d/dx (xTCx) = (C+CT)x
      • [C: symmetric]: d/dx (xTCx) = 2Cx
      • d/dx (xTx) = 2x
    • d/dx (Ax+b)T (Dx+e) = AT (Dx+e) + DT (Ax+b)
      • d/dx (Ax+b)T (Ax+b) = 2AT (Ax+b)
    • [C: symmetric]: d/dx (Ax+b)TC(Ax+b) = 2ATC(Ax+b)
  • d/dX (aTXTXb) = X(abT + baT)
    • d/dX (aTXTXa) = 2XaaT
  • d/dX (aTXTCXb) = CTXabT + CXbaT
    • d/dX (aTXTCXa) = (C + CT)XaaT
    • [C:Symmetricd/dX (aTXTCXa) = 2CXaaT
  • d/dX ((Xa+b)TC(Xa+b)) = (C+CT)(Xa+b)aT

Derivatives of Cubic Products

  • d/dx (xTAxxT) = (A+AT)xxT+xTAxI

Derivatives of Inverses

  • d/dx (Y-1) = -Y-1d/dx (Y)Y-1

Derivative of Trace

Note: matrix dimensions must result in an n*n argument for tr().

  • d/dX (tr(X)) = I
  • d/dX (tr(Xk)) =k(Xk-1)T
  • d/dX (tr(AXk)) = SUMr=0:k-1(XrAXk-r-1)T
  • d/dX (tr(AX-1B)) = -(X-1BAX-1)T
    • d/dX (tr(AX-1)) =d/dX (tr(X-1A)) = -X-TATX-T
  • d/dX (tr(ATXBT)) = d/dX (tr(BXTA)) = AB
    • d/dX (tr(XAT)) = d/dX (tr(ATX)) =d/dX (tr(XTA)) = d/dX (tr(AXT)= A
  • d/dX (tr(AXBXT)) = ATXBT + AXB
    • d/dX (tr(XAXT)) = X(A+AT)
    • d/dX (tr(XTAX)) = XT(A+AT)
    • d/dX (tr(AXTX)) = (A+AT)X
  • d/dX (tr(AXBX)) = ATXTBT + BTXTAT
  • [C:symmetricd/dX (tr((XTCX)-1A) = d/dX (tr(A (XTCX)-1) = -(CX(XTCX)-1)(A+AT)(XTCX)-1
  • [B,C:symmetricd/dX (tr((XTCX)-1(XTBX)) = d/dX (tr( (XTBX)(XTCX)-1) = -2(CX(XTCX)-1)XTBX(XTCX)-1 + 2BX(XTCX)-1

Derivative of Determinant

Note: matrix dimensions must result in an n*n argument for det().

  • d/dX (det(X)) = d/dX (det(XT)) = det(X)*X-T
    • d/dX (det(AXB)) = det(AXB)*X-T
    • d/dX (ln(det(AXB))) = X-T
  • d/dX (det(Xk)) = k*det(Xk)*X-T
    • d/dX (ln(det(Xk))) = kX-T
  • [Real] d/dX (det(XTCX)) = det(XTCX)*(C+CT)X(XTCX)-1
    • [CReal,Symmetricd/dX (det(XTCX)) = 2det(XTCX)* CX(XTCX)-1
  • [CReal,Symmetriccd/dX (ln(det(XTCX))) = 2CX(XTCX)-1

Jacobian

If y is a function of x, then dyT/dx is the Jacobian matrix of y with respect to x.

Its determinant, |dyT/dx|, is the Jacobian of y with respect to x and represents the ratio of the hyper-volumes dy and dx. The Jacobian occurs when changing variables in an integration: Integral(f(y)dy)=Integral(f(y(x)) |dyT/dx| dx).

Hessian matrix

If f is a function of x then the symmetric matrix d2f/dx2 = d/dxT(df/dx) is the Hessian matrix of f(x). A value of x for which df/dx = 0 corresponds to a minimum, maximum or saddle point according to whether the Hessian is positive definite, negative definite or indefinite.

  • d2/dx2 (aTx) = 0
  • d2/dx2 (Ax+b)TC(Dx+e) = ATCD + DTCTA
    • d2/dx2 (xTCx) = C+CT
      • d2/dx2 (xTx) = 2I
    • d2/dx2 (Ax+b)T (Dx+e) = ATD + DTA
      • d2/dx2 (Ax+b)T (Ax+b) = 2ATA
    • [C: symmetric]: d2/dx2 (Ax+b)TC(Ax+b) = 2ATCA  

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