Science Fair Project Encyclopedia
In mathematics, the dot product (also known as the scalar product and the inner product) is a sesquilinear function (·) : V × V → F, where V is a vector space over the field F, having some further properties. A formal definition is found in the article inner product space.
It is intuitively defined as
Note: A formal definition of dot product is somewhat different from this; there, the angle between a and b is defined by the above equality.
Thus, the dot product of two perpendicular vectors is always zero. If a and b are both unit vectors (i.e., of length 1), the dot product simply gives the cosine of the angle between them. Thus, given two vectors, the angle between them can be found by rearranging the above formula:
This can be understood very easily: The first vector is projected onto the second vector (the order does not matter as the dot-product is commutative) by calculating the dot-product, and afterwards "normalized" by dividing the obtained scalar value of the numerator by their scalar lengths. Thus the scalar value of the fraction must be less than or equal to 1 and can be easily translated into a angular value (As the trigonometric functions are really nothing more than Taylor approximated functions to achieve a seamless translation table of lengths into angle values and vice versa (arcsin,...). Further information is on the sine page).
It should be noted that the geometric interpretation of the inner product is generally only used for with . When working in higher dimensions, in spaces over other fields, or with modules, the only definition of the inner product is the following:
The dot product is particularly used in the calculation of net force. If b is a unit vector, then the dot product gives the projection of a in the direction b. In mechanics, this gives the component of a force in that direction.
Work is the dot product of force and displacement.
The definition has the following consequences. The dot product is commutative:
From these it follows directly that the dot product of two vectors a = [a1 a2 a3] and
b = [b1 b2 b3] given in coordinates can be computed particularly easily as
where bT denotes the transpose of the matrix b.
The dot product satisfies all the axioms of an inner product. In an abstract vector space, the notion of angle between the elements of the space can be defined in terms of the inner product.
Proof that the two forms of definition are equivalent
We have already shown that the theorem
follows from the definition
To prove that these are two equivalent ways of defining the dot product, we shall now instead use the former to derive the latter.
Note: This proof is shown for 3-dimensional vectors, but is readily extendable to n-dimensional vectors given mutually perpendicular unit vectors.
Consider a vector
Repeated application of the Pythagorean theorem yields
But this is the same as
so we conclude that taking the dot product of a vector v with itself yields the squared length of the vector.
- Lemma 1
Now consider two vectors a and b extending from the origin, separated by an angle θ. A third vector c may be defined as
creating a triangle with sides a, b, and c. According to the law of cosines, we have
Substituting dot products for the squared lengths according to Lemma 1, we get
- . (1)
But as c ≡ a − b, we also have
which, according to the distributive law, expands to
- . (2)
Merging the two c · c equations, (1) and (2), we obtain
Subtracting a · a + b · b from both sides and dividing by −2 leaves
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