''q''-derivative

In mathematics, in the area of combinatorics, the q-derivative, or Jackson derivative, is a q-analog of the ordinary derivative, introduced by Frank Hilton Jackson. It is the inverse of Jackson's q-integration. For other forms of q-derivative, see (Chung et al. (1994)).

Definition

The q-derivative of a function f(x) is defined as

\left(\frac{d}{dx}\right)_q f(x)=\frac{f(qx)-f(x)}{qx-x}.

It is also often written as $D_qf(x)$ . The q-derivative is also known as the Jackson derivative.

Formally, in terms of Lagrange's shift operator in logarithmic variables, it amounts to the operator

D_q= \frac{1}{x} ~ \frac{q^{d~~~ \over d (\ln x)} -1}{q-1} ~,

which goes to the plain derivative $\to {\frac {d}{dx}}$ as $q \to 1$ .

It is manifestly linear,

\displaystyle D_q (f(x)+g(x)) = D_q f(x) + D_q g(x)~.

It has product rule analogous to the ordinary derivative product rule, with two equivalent forms

\displaystyle D_q (f(x)g(x)) = g(x)D_q f(x) + f(qx)D_q g(x) = g(qx)D_q f(x) + f(x)D_q g(x).

Similarly, it satisfies a quotient rule,

\displaystyle D_q (f(x)/g(x)) = \frac{g(x)D_q f(x) - f(x)D_q g(x)}{g(qx)g(x)},\quad g(x)g(qx)\neq 0.

There is also a rule similar to the chain rule for ordinary derivatives. Let $g(x) = c x^k$ . Then

\displaystyle D_q f(g(x)) = D_{q^k}(f)(g(x))D_q(g)(x).

The eigenfunction of the q-derivative is the q-exponential e_q(x).

Relationship to ordinary derivatives

Q-differentiation resembles ordinary differentiation, with curious differences. For example, the q-derivative of the monomial is:

\left(\frac{d}{dz}\right)_q z^n = \frac{1-q^n}{1-q} z^{n-1} = [n]_q z^{n-1}

where $[n]_q$ is the q-bracket of n. Note that $\lim_{q\to 1}[n]_q = n$ so the ordinary derivative is regained in this limit.

The n-th q-derivative of a function may be given as:

(D^n_q f)(0)= \frac{f^{(n)}(0)}{n!} \frac{(q;q)_n}{(1-q)^n}= \frac{f^{(n)}(0)}{n!} [n]_q!

provided that the ordinary n-th derivative of f exists at x = 0. Here, $(q;q)_n$ is the q-Pochhammer symbol, and $[n]_{q}!$ is the q-factorial. If $f(x)$ is analytic we can apply the Taylor formula to the definition of $D_q(f(x))$ to get

\displaystyle D_q(f(x)) = \sum_{k=0}^{\infty}\frac{(q-1)^k}{(k+1)!} x^k f^{(k+1)}(x).

A q-analog of the Taylor expansion of a function about zero follows:

f(z)=\sum_{n=0}^\infty f^{(n)}(0)\,\frac{z^n}{n!} = \sum_{n=0}^\infty (D^n_q f)(0)\,\frac{z^n}{[n]_q!}

References

F. H. Jackson (1908), On q-functions and a certain difference operator, Trans. Roy. Soc. Edin., 46, 253-281.
Exton, H. (1983), q-Hypergeometric Functions and Applications, New York: Halstead Press, Chichester: Ellis Horwood, 1983, ISBN 0853124914, ISBN 0470274530, ISBN 978-0470274538
Victor Kac, Pokman Cheung, Quantum Calculus, Universitext, Springer-Verlag, 2002. ISBN 0-387-95341-8
Chung, K. S., Chung, W. S., Nam, S. T., & Kang, H. J. (1994). New q-derivative and q-logarithm. International Journal of Theoretical Physics, 33, 2019-2029.

''q''-derivative

Definition

Relationship to ordinary derivatives

See also

References

Further reading