<< Chapter < Page | Chapter >> Page > |
In order to propely discuss the concept of vector spaces in linear algebra, it is necessary to develop the notion of a set of “scalars” by which we allow a vector to be multiplied. A framework within which our concept of real numbers would fit is desireable. Thus, we would like a set with two associative, commutative operations (like standard addition and multiplication) and a notion of their inverse operations (like subtraction and division). The mathematical algebraic construct that addresses this idea is the field. A field is a set together with two binary operations and such that the following properties are satisfied.
While this definition is quite general, the two fields used most often in signal processing, at least within the scope of this course, are the real numbers and the complex numbers, each with their typical addition and multiplication operations.
The reader is undoubtedly already sufficiently familiar with the real numbers with the typical addition and multiplication operations. However, the field of complex numbers with the typical addition and multiplication operations may be unfamiliar to some. For that reason and its importance to signal processing, it merits a brief explanation here.
The notion of the square root of originated with the quadratic formula: the solution of certain quadratic equations mathematically exists only if the so-called imaginary quantity could be defined. Euler first used for the imaginary unit but that notation did not take hold untilroughly Ampère's time. Ampère used the symbol to denote current (intensité de current).It wasn't until the twentieth century that the importance of complex numbers to circuit theory became evident. By then, using for current was entrenched and electrical engineers now choose for writing complex numbers.
An imaginary number has the form . A complex number , , consists of the ordered pair ( , ), is the real component and is the imaginary component (the is suppressed because the imaginary component of the pair is always in the second position). The imaginary number equals ( , ). Note that and are real-valued numbers.
[link] shows that we can locate a complex number in what we call the complex plane . Here, , the real part, is the -coordinate and , the imaginary part, is the -coordinate. From analytic geometry, we know that locations in the plane can be expressed as the sum of vectors, with the vectors corresponding to the and directions. Consequently, a complex number can be expressed as the (vector) sum where indicates the -coordinate. This representation is known as the Cartesian form of . An imaginary number can't be numerically added to a real number;rather, this notation for a complex number represents vector addition, but it provides a convenient notation when we perform arithmetic manipulations.
Notification Switch
Would you like to follow the 'Signals and systems' conversation and receive update notifications?