Difference between revisions of "Inner product"
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− | ''scalar product, dot product, | + | ''scalar product, dot product, $\def\vect#1{\mathbf{#1}}\def\modulus#1{\left|#1\right|}(\vect a,\vect b)$ of two non-zero vectors $\vect a$ and $\vect b$'' |
− | The product of their lengths and the cosine of the angle | + | The product of their lengths and the cosine of the angle $\phi$ between them: |
− | + | \[(\vect a,\vect b)=\modulus{\vect a}\modulus{\vect b}\cos\phi.\] | |
− | + | $\phi$ is taken to be that angle between the vectors not exceeding $\pi$. When $\vect a$ or $\vect b$ is zero, the inner product is taken to be zero. The inner product $(\vect a,\vect a)=\vect a^2=\modulus{\vect a}^2$ is called the scalar square of the vector $\vect a$ (see [[Vector algebra]]). | |
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+ | The inner product of two $n$-dimensional vectors $\vect a=(a_1,\dotsc,a_n)$ and $\vect b=(b_1,\dotsc,b_n)$ over the real numbers is given by | ||
+ | \[(\vect a,\vect b)=a_1b_1+\dotsb+a_nb_n.\] | ||
In the complex case it is given by | In the complex case it is given by | ||
− | + | \[(\vect a,\vect b)=a_1\bar b_1+\dotsb+a_n\bar b_n\] | |
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An infinite-dimensional [[Vector space|vector space]] admitting an inner product and complete with respect to it is called a [[Hilbert space|Hilbert space]]. | An infinite-dimensional [[Vector space|vector space]] admitting an inner product and complete with respect to it is called a [[Hilbert space|Hilbert space]]. | ||
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====Comments==== | ====Comments==== | ||
− | More generally, an inner product on a real vector space is a symmetric [[Bilinear form|bilinear form]] | + | More generally, an inner product on a real vector space is a symmetric [[Bilinear form|bilinear form]] $f$ which is positive definite, i.e., $f(x,x)>0$ for all $x\neq 0$. A (unitary) inner product on a complex vector space is likewise defined as a Hermitian (i.e., with $f(y,x)=\overline{f(x,y)}$) [[Sesquilinear form|sesquilinear form]], with complex conjugation as automorphism, which is positive definite. In finite-dimensional spaces one can always find an orthonormal basis in which $f$ takes the standard form $f(x,y)=\sum_{i=1}^n x_iy_i$, respectively $\sum_{i=1}^n x_i\bar y_i$. |
Besides the inner product (which can be defined in arbitrary dimensions), in three-dimensional space one also has the [[Vector product|vector product]]. | Besides the inner product (which can be defined in arbitrary dimensions), in three-dimensional space one also has the [[Vector product|vector product]]. | ||
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====References==== | ====References==== | ||
<table><TR><TD valign="top">[a1]</TD> <TD valign="top"> V.I. Istrăţescu, "Inner product structures" , Reidel (1987)</TD></TR></table> | <table><TR><TD valign="top">[a1]</TD> <TD valign="top"> V.I. Istrăţescu, "Inner product structures" , Reidel (1987)</TD></TR></table> | ||
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+ | {{TEX|done}} |
Latest revision as of 04:43, 22 March 2013
scalar product, dot product, $\def\vect#1{\mathbf{#1}}\def\modulus#1{\left|#1\right|}(\vect a,\vect b)$ of two non-zero vectors $\vect a$ and $\vect b$
The product of their lengths and the cosine of the angle $\phi$ between them: \[(\vect a,\vect b)=\modulus{\vect a}\modulus{\vect b}\cos\phi.\] $\phi$ is taken to be that angle between the vectors not exceeding $\pi$. When $\vect a$ or $\vect b$ is zero, the inner product is taken to be zero. The inner product $(\vect a,\vect a)=\vect a^2=\modulus{\vect a}^2$ is called the scalar square of the vector $\vect a$ (see Vector algebra).
The inner product of two $n$-dimensional vectors $\vect a=(a_1,\dotsc,a_n)$ and $\vect b=(b_1,\dotsc,b_n)$ over the real numbers is given by \[(\vect a,\vect b)=a_1b_1+\dotsb+a_nb_n.\] In the complex case it is given by \[(\vect a,\vect b)=a_1\bar b_1+\dotsb+a_n\bar b_n\] An infinite-dimensional vector space admitting an inner product and complete with respect to it is called a Hilbert space.
Comments
More generally, an inner product on a real vector space is a symmetric bilinear form $f$ which is positive definite, i.e., $f(x,x)>0$ for all $x\neq 0$. A (unitary) inner product on a complex vector space is likewise defined as a Hermitian (i.e., with $f(y,x)=\overline{f(x,y)}$) sesquilinear form, with complex conjugation as automorphism, which is positive definite. In finite-dimensional spaces one can always find an orthonormal basis in which $f$ takes the standard form $f(x,y)=\sum_{i=1}^n x_iy_i$, respectively $\sum_{i=1}^n x_i\bar y_i$.
Besides the inner product (which can be defined in arbitrary dimensions), in three-dimensional space one also has the vector product.
References
[a1] | V.I. Istrăţescu, "Inner product structures" , Reidel (1987) |
Inner product. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Inner_product&oldid=15855