q-derivative

In mathematics, in the area of combinatorics and quantum calculus, 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[1][2][3]

It is also often written as . 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

which goes to the plain derivative as .

It is manifestly linear,

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

Similarly, it satisfies a quotient rule,

There is also a rule similar to the chain rule for ordinary derivatives. Let . Then

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

Relationship to ordinary derivatives

Q-differentiation resembles ordinary differentiation, with curious differences. For example, the q-derivative of the monomial is[2]:

where is the q-bracket of n. Note that so the ordinary derivative is regained in this limit.

The n-th q-derivative of a function may be given as[3]:

provided that the ordinary n-th derivative of f exists at x = 0. Here, is the q-Pochhammer symbol, and is the q-factorial. If is analytic we can apply the Taylor formula to the definition of to get

A q-analog of the Taylor expansion of a function about zero follows[2]:

Higher order -derivatives

Th following representation for higher order -derivatives is known[4][5]:

is the -binomial coefficient. By changing the order of summation as , we obtain the next formula [4][6]:

Higher order -derivatives are used to -Taylor formula and the -Rodrigues' formula (the formula used to construct -orthogonal polynomials[4]).

Generalizations

Post Quantum Calculus

Post quantum calculus is a generalization of the theory of quantum calculus, and it uses the following operator[7][8]:

Hahn difference

Wolfgang Hahn introduced the following operator (Hahn difference)[9][10]:

When this operator reduces to -derivative, and when it reduces to forward difference. This is a successful tool for constructing families of orthogonal polynomials and investigating some approximation problems[11][12][13].

-derivative

-derivative is an operator defined as follows[14][15]:

In the definition, is a given interval, and is any continuous function that strictly monotonically increases (i.e ). When then this operator is -derivative, and when this operator is Hahn difference.

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See also

References

  1. F. H. Jackson (1908), On -functions and a certain difference operator, Trans. Roy. Soc. Edin., 46, 253-281.
  2. Victor Kac, Pokman Cheung, Quantum Calculus, Universitext, Springer-Verlag, 2002. ISBN 0-387-95341-8
  3. Ernst, T. (2012). A comprehensive treatment of -calculus. Springer Science & Business Media.
  4. Koepf, Wolfram. (2014). Hypergeometric Summation. An Algorithmic Approach to Summation and Special Function Identities. 10.1007/978-1-4471-6464-7.
  5. Koepf, W., Rajković, P. M., & Marinković, S. D. (2007). Properties of -holonomic functions.
  6. Annaby, M. H., & Mansour, Z. S. (2008). -Taylor and interpolation series for Jackson -difference operators. Journal of Mathematical Analysis and Applications, 344(1), 472-483.
  7. Gupta V., Rassias T.M., Agrawal P.N., Acu A.M. (2018) Basics of Post-Quantum Calculus. In: Recent Advances in Constructive Approximation Theory. Springer Optimization and Its Applications, vol 138. Springer.
  8. Duran, U. (2016). Post Quantum Calculus, M.Sc. Thesis in Department of Mathematics, University of Gaziantep Graduate School of Natural & Applied Sciences.
  9. Hahn, W. (1949). Math. Nachr. 2: 4-34.
  10. Hahn, W. (1983) Monatshefte Math. 95: 19-24.
  11. Foupouagnigni, M.: Laguerre-Hahn orthogonal polynomials with respect to the Hahn operator: fourth-order difference equation for the rth associated and the Laguerre-Freud equations for the recurrence coefficients. Ph.D. Thesis, Universit´e Nationale du B´enin, B´enin (1998).
  12. Kwon, K., Lee, D., Park, S., Yoo, B.: KyungpookMath. J. 38, 259-281 (1998).
  13. Alvarez-Nodarse, R.: J. Comput. Appl. Math. 196, 320-337 (2006).
  14. Auch, T. (2013): Development and Application of Difference and Fractional Calculus on Discrete Time Scales. PhD thesis, University of Nebraska-Lincoln.
  15. Hamza, A., Sarhan, A., Shehata, E., & Aldwoah, K. (2015). A General Quantum Difference Calculus. Advances in Difference Equations, 2015(1), 182.
  • Exton, H. (1983), -Hypergeometric Functions and Applications, New York: Halstead Press, Chichester: Ellis Horwood, 1983, ISBN 0853124914, ISBN 0470274530, ISBN 978-0470274538
  • Chung, K. S., Chung, W. S., Nam, S. T., & Kang, H. J. (1994). New -derivative and -logarithm. International Journal of Theoretical Physics, 33, 2019-2029.

Further reading

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